cGAS-STING signalling regulates microglial chemotaxis in genome instability

Abstract Defective DNA damage signalling and repair is a hallmark of age-related and genetic neurodegenerative disease. One mechanism implicated in disease progression is DNA damage-driven neuroinflammation, which is largely mediated by tissue-resident immune cells, microglia. Here, we utilise human microglia-like cell models of persistent DNA damage and ATM kinase deficiency to investigate how genome instability shapes microglial function. We demonstrate that upon DNA damage the cytosolic DNA sensing cGAS-STING axis drives chronic inflammation and a robust chemokine response, exemplified by production of CCL5 and CXCL10. Transcriptomic analyses revealed that cell migratory pathways were highly enriched upon IFN-β treatment of human iPSC-derived microglia, indicating that the chemokine response to DNA damage mirrors type I interferon signalling. Furthermore, we find that STING deletion leads to a defect in microglial chemotaxis under basal conditions and upon ATM kinase loss. Overall, this work provides mechanistic insights into cGAS-STING-dependent neuroinflammatory mechanisms and consequences of genome instability in the central nervous system.


Introduction
Accumulation of DNA damage in the central nervous system (CNS) is commonly observed in ageing and neurodegenerative diseases, including Alzheimer's and amyotrophic lateral sclerosis (1)(2)(3).Additionally, loss-of-function mutations in DNA damage response (DDR) genes underpin neurodegeneration in monogenic disorders, such as ataxia with oculomotor apraxia types 1-5 and ataxia-telangiectasia.Such vulnerability of the CNS to DDR defects is thought to stem from the interplay between cell intrinsic effects of DNA damage on post-mitotic neurons and glia, as well as extrinsic signals resulting from glia-driven neuroinflammation ( 4 ,5 ).
One mechanism linking genome instability and neuroinflammation is the cytosolic DNA sensing cGAS-STING pathway.Although responsible for mobilising antimicrobial responses to cytosolic pathogenic DNA during infection, the cGAS-STING pathway can mount innate immune responses to host DNA aberrantly localised in the cytosol following DNA damage ( 6 ).To initiate the response, the nucleotidyl transferase cGAS binds pathogenic double-stranded DNA (ds-DNA) in the cytosol, catalysing synthesis of 2 ,3 -cyclic GMP-AMP (cGAMP).cGAMP activates the immune adaptor stimulator of interferon genes (STING) at the endoplasmic reticulum (ER), inducing STING oligomerisation and translocation to the Golgi, where it recruits the TBK1 kinase and the interferon regulatory transcription factor IRF3. STING then acts as a platform for TBK1 autophosphorylation at S172, as well as phosphorylation of STING at S366 and IRF3 at S396, culminating in nuclear translocation of IRF3.STING signalling also activates NF-κB, leading to IRF3-and NF-κB-dependent transcription of type I interferons, interferon-stimulated genes (ISGs), and pro-inflammatory cytokines which mount the antimicrobial response ( 7 ,8 ).
In the absence of infection, cytosolic accumulation of host DNA arising from genome instability can also activate STING-dependent autoimmunity.One such example is cGAS activation by nucleosome tethering at ruptured micronuclei, which can form during mitosis in cells harbouring unresolved DNA damage (9)(10)(11).Moreover, cGAS is activated by nuclear dsDNA, RNA:DNA hybrids, telomeric DNA and mitochondrial DNA which can accumulate in the cytosol following genotoxic or mitochondrial stress (12)(13)(14)(15).Thus, cGAS-STING promotes inflammation in response to diverse self-DNA species.
In the brain, the strongest response to cGAS-STING activation occurs in microglia, the resident macrophages of the CNS ( 16 ).Microglia maintain CNS homeostasis via surveillance of the microenvironment, phagocytosis of apoptotic cells and / or debris, synaptic pruning, and production of neurotrophic factors (17)(18)(19)(20).During infection or injury, microglia can transition towards a heterogenous 'reactive' state typified by enhanced phagocytosis, motility, proliferation, and production of inflammatory mediators and reactive oxygen / nitrogen species ( 21 ).However, chronic microglial reactivity is implicated in neurodegenerative disease, including those driven by genome instability, such as ataxia-telangiectasia (A-T) ( 5 ,22 ).
A-T is caused by loss-of-function mutations in ATM, a protein kinase which coordinates cellular responses to cytotoxic DNA double strand breaks (DSBs) and oxidative stress.More broadly, ATM preserves homeostasis by regulating redox balance, glucose metabolism and immunity ( 23 ).In humans, A-T manifests as cerebellar degeneration and ataxia, and microglia-driven neuroinflammation is increasingly implicated in disease phenotypes.Microglial activation is observed in Atm-deficient murine microglia and correlates with motor neuron loss in the spinal cord of Atm-deficient rats (24)(25)(26)(27).Furthermore, we previously demonstrated that ATM loss in human microglia-like cells activates RELB / p52 NF-κB signalling and drives aberrant phagocytic activity, resulting in damage to the neuronal network in vitro ( 28 ).Interestingly, cerebellar microglia exhibit characteristics which may predispose them to exacerbated immune responses to genome instability, including heightened immune vigilance and enhanced proliferation ( 29 ,30 ).Indeed, gene signatures enriched in cytosolic DNA sensing, antiviral immunity, and proliferation are upregulated specifically in cerebellar microglia in A-T ( 31 ).In addition, ATM deficiency activates cytosolic DNA sensing in diverse cell models, including primary murine microglia and A-T patient-derived brain organoids ( 6 , 25 , 32-35 ).STING ac-tivation in ATM deficiency is also linked with neuronal damage via microglial secretion of IL-1 β and inflammatory responses mediated by senescent astrocytes ( 25 ,32 ).However, the molecular mechanisms of how STING signalling and type I interferon production shapes microglial function in genome instability remain unclear.
Here, we investigate how loss of ATM kinase and persistent DNA damage regulate microglial function.We find that genome instability drives chronic chemokine production in human microglia-like cells and the chemokine response is regulated by the cGAS-STING pathway.In agreement with this, bulk RNA-sequencing (RNA-seq) of iPSC-derived microglia treated with IFNβ implicated type I interferon signalling in the governance of microglial migration.Indeed, we find that STING deletion leads to defective microglial migration in basal conditions and upon loss of A TM function.W e propose that STING-mediated chronic chemokine production may amplify neuroinflammation in genome instability via several different mechanisms, including the recruitment of peripheral immune cells to the CNS and excessive energy expenditure.Overall, this work provides mechanistic insight into STING-dependent regulation of microglial function upon persistent DNA damage.
All cell lines were cultured at 37ºC in 5% CO 2 and 95% humidity.Cells were routinely tested for mycoplasma and experiments were performed below passage 35.

RNA interference
siRNA duplexes were synthesised by Merck and used at a final concentration of 25 nM unless stated otherwise (sequences are listed in Supplementary Table S1 ).siRNA was delivered by forward transfection using Lipofectamine® RNAiMAX™ Transfection Reagent (Invitrogen™) according to manufacturer's instructions.Media was changed 8 h posttransfection to limit toxicity and cells were harvested 72 h post-transfection.

Chemical treatments
The ATM inhibitor AZD1390 (ATMi; Selleck Chemicals) was used at 10 nM for 1-9 days with replenishment of the inhibitor every 2 days.To induce ATM activation, cells were treated with 1 μM camptothecin (CPT; Cayman Chemical Company) for 1 h.The STING agonist diABZi (Selleck Chemicals) was used at 1 μM.To induce DNA damage, cells were treated with 250 nM etoposide (ETO; Cayman Chemical Company), 30 nM mitomycin C (MMC; Santa Cruz), or 150 nM aphidicolin (APH; Merck) for 6 days.To induce apoptosis, cells were treated with 1 μM staurosporine for 6 h.Treatment times are indicated in figure captions.For compounds dissolved in DMSO, DMSO concentration was equivalent between conditions and < 0.1% (v / v).

Cell synchronisation in G2 cell cycle phase, inhibition of transcription and antioxidant treatments
Exponentially growing cells were pre-treated with 10 nM ATMi or DMSO as a control for 5 days, then treated for an additional 24 h in the presence (synchronised in G2 cell cycle phase) or absence (asynchronised) of 9 μM CDK1 inhibitor RO-3306 (CDK1i; Tocris Bioscience) prior to collection.
For antioxidant treatments, cells were treated for 72 h with ATMi, or DMSO as a control, and for an additional 72 h in the presence of 10 μM 4,5-dihydroxy-1,3-benzenedisulfonic acid (tiron) or 5 μM N -acetyl-l -cysteine (NAC) to scavenge intracellular reactive oxygen species (ROS), or with 100 U / ml catalase to scavenge extracellular ROS (all Merck).Culture medium containing ROS scavengers and ATMi, or DMSO, was replenished daily.

Cell cycle analysis
Cells were pulsed with 10 μM BrdU for 30 min, then collected by trypsinisation and fixed in ice-cold 70% ethanol for at least 30 min.After removal of ethanol by centrifugation, cells were incubated in 2 M HCl containing 0.1 mg / ml pepsin for 20 min at 37ºC.Cells were washed several times in PBS and 1% (v / v) HI-FBS in PBS, collected by centrifugation at 350 g for 5 min and incubated with anti-BrdU antibody at 1:100 dilution in 1% (v / v) HI-FBS-PBS for 1 h at 22ºC.Cells were washed in PBS and incubated with AlexaFluor 488 goat anti-mouse secondary antibody diluted 1:200 in 1% (v / v) HI-FBS-PBS for 45 min at 22ºC.Samples were further treated with 100 μg / ml RNase A (QIAGEN) for 30 min at 37ºC, supplemented with 100 ng / ml propidium iodide (PI) and analysed on the green FL1-A and red FL2-A channels using an Accuri™ C6 Plus flow cytometer (BD Biosciences).

Biochemical fractionation
Cell pellets were harvested by trypsinisation and resuspended in plasma membrane lysis buffer (20 mM Tris-HCl, pH 7.4, 2.5 mM MgCl 2 , 0.3% (v / v) NP-40) supplemented with protease / phosphatase inhibitors as above.After incubation on ice for 15 min, lysates were centrifuged for 10 min at 1 500 g , 4ºC.The supernatant served as the cytoplasmic fraction and the pellet containing nuclei was resuspended in 20 mM phosphate buffer, 0.5 M NaCl, 1 mM EDTA, 0.75% (v / v) Triton X-100, glycerol 10% (v / v) and 5 mM MgCl 2 .After incubation on ice for 15 min, nuclear lysates were centrifuged for 10 min at 20 000 g to obtain the nuclear fraction.The protein content of cytosolic fractions was determined by Bradford and equal volumes of cytoplasmic and nuclear fractions were analysed by SDS-PAGE.

Immunoblotting
Proteins were separated using 10 or 4-16% Tris-glycine SDS-PAGE and transferred onto Immobilon®-FL PVDF membranes, which were blocked using Intercept®-TBS blocking buffer (LI-COR Biosciences).Primary antibodies were diluted in Intercept®-TBS, 0.1% (v / v) Tween®20 and secondary antibodies were diluted in Intercept®-TBS, 0.1% (v / v) Tween®20, 0.01% (w / v) SDS.Antibodies are detailed in Supplementary Table S1 .Membranes were visualized using an Odyssey® CLx Imaging System and quantification was performed using Image Studio™ Lite Software (both LI-COR Biosciences).Band intensities were normalised to loading controls, or to the corresponding total protein for phosphorylated proteins, and presented as fold-change relative to the experimental control.Immunoblots are representative of at least three independent experiments.

Brain tissue homogenisation and processing
Blocks of fresh frozen cerebellar tissues from individuals with A-T and that of individuals with no known diseases of the CNS (controls) were obtained from the NIH Neurobiobank at the University of Maryland, Baltimore, MD (United States).The use of samples was covered by the University of Maryland's IRB approval no.HP-00042077 and the HTA site license no.12196 that permits work with human tissue at the Department of Biochemistry (University of Cambridge, UK).The A-T and control tissue pairs were matched by age and gender ( Supplementary Table S2 ).The tissues were cut into 20μm thick sections with a cryostat (Leica CM 1950) maintained at -20ºC.To extract the RNA, 5-6 sections were collected into a tube containing lysing matrix beads (1.4 mm ceramic spheres, MP Biologicals), supplemented with 1 ml of the TRI Reagent® (Merck), and snap frozen on dry ice.After thawing, samples were homogenized by vortexing and the RNA was extracted as previously described ( 39 ).
To extract proteins, tissue sections were collected into tubes with lysing matrix beads (as above) containing RIPA buffer supplemented with protease / phosphatase inhibitors as above and snap frozen in liquid nitrogen.After thawing on ice, tissues were homogenized by intermittent vortexing at 4ºC, then centrifuged at 20 000 g for 20 min at 4ºC.Protein lysate concentrations were measured and prepared for SDS-PAGE analyses as above.

RT-qPCR
Total RNA from adherent cells was extracted using the RNeasy Mini Kit (QIAGEN) and treated with DNase I (Thermo Fisher Scientific) according to manufacturer's instructions.RNA integrity was assessed by agarose gel electrophoresis and purity was determined by measuring the ratio of absorbance at 260 / 280 ( A 260 / 280 ) and 260 / 230 ( A 260 / 230 ) using a NanoDrop™ ND-1000 Spectrophotometer (Thermo Fisher Scientific).RNA with intact 28S and 18S ribosomal RNA bands at a ratio of approximately 2:1 with A 260 / 280 of ∼2 and A 260 / 230 of 1.8 -2.2 was used for reverse transcription (RT).When tissues were used as a source, the integrity of DNase I-treated RNA was determined using the Agilent RNA 6000 Pico Kit and an Agilent 2100 Bioanalyzer (Agilent Technologies).RNA with RIN values > 4 was used for RT.
RT was performed with 400 ng RNA per 20 μl reaction using the qPCR cDNA Synthesis Kit (PCR Biosystems).cDNA was treated with RNase H (New England Biolabs) for 20 min at 37ºC and diluted 1:5 prior to qPCR.
Primers for qPCR were synthesised by Merck and used at 200 nM final (sequences in Supplementary Table S1 ).Primer efficiencies were assessed by standard curve and specificity was confirmed by melt curve analysis and agarose gel electrophoresis.qPCR was performed using 2 × qPCR BIO SyGreen Blue Mix Lo-ROX (PCR Biosystems) in triplicate 10μl reactions in 384-well plates (Applied Biosystems).Amplification was performed on a QuantStudio™5 Real-Time PCR System (Thermo Fisher Scientific) using the following cycling parameters: initial denaturation and polymerase activation at 95ºC for 2 min; 40 cycles of 95ºC for 5 s and 60ºC for 30 s, and a subsequent melt step: 95ºC for 15 s, 60ºC for 60 s, 95ºC for 15 s.Data was analysed using the QuantStudio™ Design & Analysis Software (Thermo Fisher Scientific).Mean C q values of technical triplicates were normalised to the reference genes RPS13 or IPO8 and experimental controls using the δδC q method ( 40 ).Data is presented as average log 2 foldchange ± SD except for TFAM mRNA, which is presented as fold change, and human tissue data, which is presented as 2 −δCq .

RNAseq of IFNβ-treated human iCell microglia
iCell human microglia (FUJIFILM Cellular Dynamics, Inc.) were derived from peripheral blood mononuclear cells from a donor with no known disease phenotypes.The iCell microglia cells were acquired by AstraZeneca in compliance with the FUJIFILM Cellular Dynamics, Inc. materials transfer agreement.The use of iCell microglia was reviewed and supported by the AstraZeneca Human Biological Sample Governance Team.
Three independent vials of iCell microglia were seeded at 5 × 10 4 cells per well across three independent 96-well plates and treated the following day with vehicle or 5 ng / ml human IFNβ (R&D Systems).Cells were treated for 6 or 24 h prior to collection and stored at -80ºC prior to RNA extraction.
For cell lysis, RNAdvance Cell v2 (Beckman Coulter) was added to iCell Microglia in 96-well plates on dry ice.Plates were warmed to room temperature, treated with Proteinase K and cells were lysed by gentle pipetting followed by incubation at room temperature for 30 min.RNA extraction was performed according to manufacturer's protocol on a Biomek i7 Hybrid robotic workstation (Beckman Coulter).mRNA enrichment and sequencing library preparation was performed using KAPA mRNA HyperPrep Kit (Roche) according to the manufacturer's protocol on a Tecan Fluent® liquid handler.Library quality was assessed on a fragment analyser instrument using SS NGS fragment kit (1-6000 bp; Agilent).Sequencing was performed on a NovaSeq 6000 using a 200 cycles SP Reagent Kit v1.5 (both Illumina) at a loading concentration of 1.85 nM.Sequencing generated 194.6 Gb of data with Q30 of over 91.6%.

Transcriptomics data analysis
FastQC files were generated and trimmed with TrimGalore ( 41 ) and quality review was performed by FastQC ( 42 ) before and after quality trim.Reads were aligned with STAR aligner (version 2.6.1d,using the default settings) to the HG38 human genome and ENSEMBL94 annotation GTF file.After alignment and summarization with featureCounts of the Subread package (feature Counts release 1.6.3 and picard version 2.18.21), samples were normalized using voom (limma package) and differential gene expression analysis was carried out with limma implemented in R. FDR adjusted P -value < 0.05 was used as the cut-off (Benjamini-Hochberg method).Gene annotations were obtained by biomaRt.
The sample preparation, RNAseq and transcriptomics data analysis were performed by AstraZeneca.The raw FASTQ data files cannot be made publicly available in accordance with the UK General Data Protection Regulation and the Data Protection Act 2018.The normalized read count matrices are deposited in the ArrayExpress database (accession E-MTAB-13404).

Pathway and network analyses
For protein interaction network analysis and visualization Cytoscape was used (version 3.8.0)and the StringApp plugin using a confidence score cutoff of 0.7 (high confidence) ( 43 ,44 ).Gene Ontology (GO) and KEGG database enrichment was performed using R and the clusterProfiler package with an adjusted P -value cutoff of 0.05 ( 45 ).

Measurements of cytokine / chemokine secretion
Following 72 h pre-treatment with 10 nM AZD1390 or DMSO as a control, wild-type (WT) and STING1 KO HMC3 cells were seeded at a density of 21 000 cells / cm 2 in 6-well plates.After 48 h, cells were washed in PBS and placed in DMEM supplemented with 0.5% (v / v) HI-FBS.Cells were stimulated with 1 μM diABZi for 24 h prior to collection.Conditioned medium was centrifuged at 400 g for 10 min at 4ºC to pellet cells and debris, then snap frozen on dry ice and stored at -80ºC until use.After collection of medium, remaining cells were lysed in RIPA buffer and total protein content was measured by Bradford assay.The overall protein content was comparable between treatments.
Secretion of IFN-α2a, IFNβ and CXCL10 was measured using a Mesoscale Discovery (MSD) U-PLEX assay following the manufacturer's protocol.Plates were read on a MESO SECTOR S 600 (MSD), and data was analysed using MSD Discovery Workbench (version 4).

Immunofluorescence
Cells were seeded on glass coverslips and fixed in 4% (w / v) paraformaldehyde for 15 min at room temperature.Coverslips were then permeabilised with 0.2% (v / v) Triton X-100 for 10 min and blocked in 3% (w / v) BSA, 0.05% (v / v) Tween®20, 0.3 M glycine in PBS for 1 h.For detection of IRF3, coverslips were fixed and permeabilised in ice-cold methanol for 5 min before blocking.Antibodies were diluted in blocking buffer ( Supplementary Table S1 ) and cells were incubated with primary antibodies at 4ºC overnight in a humidified environment.Coverslips were then washed in PBS with 0.1% (v / v) Tween®20 (PBST) and incubated with secondary antibodies for 45 min at room temperature.Coverslips were washed in PBST before mounting onto glass slides using Fluoroshield™ mounting medium (Merck) supplemented with 1.5 μg / ml DAPI.
Detection of cytosolic dsDNA was performed as previously described with amendments ( 46 ).Coverslips were fixed as above and permeabilised with 0.2% (v / v) Triton X-100 for 5 min at 4ºC.To remove cytosolic RNA, coverslips were treated with 2 mg / ml RNase A (QIAGEN) for 30 min at 37ºC, then washed in PBS.Antibody specificity was validated by treating with 200 U / ml DNase I (Thermo Fisher Scientific) for 30 min at 37ºC.Coverslips were blocked in 3% (w / v) BSA, 0.3 M glycine in PBS.Coverslips were then processed as described above, however Tween®20 was omitted from subsequent buffers to limit permeabilization of the nuclear membrane.

Microscopy and image analysis
Fluorescence microscopy was performed using a Zeiss Axio Imager M2 or Zeiss Axio Imager Z2 epifluorescent microscope using a 20 × objective.Laser scanning confocal microscopy was performed using a Nikon Eclipse Ti microscope with 40 × or 60 × oil-immersion objectives.
Images were processed and analysed using FIJI (ImageJ; National Institutes of Health) or CellProfiler (Broad Institute).To analyse nuclear translocation of IRF3, the nuclei and cytoplasm were segmented in CellProfiler using DAPI and vinculin staining, respectively.Mean fluorescence intensity was determined in each compartment and expressed as a ratio of nuclear:cytoplasmic (N:C) intensity.Cells with nuclear translocation were determined as the percentage of cells with an N:C ratio > 1.5.

Quantification of micronuclei (MN)
Cells were grown on glass coverslips, fixed and DAPI-stained as above.Blinded MN scoring was performed using the Im-ageJ Cell Counter plugin in accordance with published criteria ( 47 ).Mitotic and apoptotic cells were manually excluded from analysis.For detection of cGAS-positive MN, an intensity threshold was set, and cGAS-positive MN were identified by particle analysis in ImageJ.The number of cGAS-positive MN was normalised to the number of cells scored ( > 100 cells per independent experiment).

Quantification of cytoplasmic dsDNA
Cytoplasmic dsDNA intensity was analysed on maximum intensity projections of confocal Z-stacks using CellProfiler.Nuclei were segmented based on DAPI staining.The resulting nuclei and TOM20 staining were then used to define the whole-cell boundary and the nuclear region was subtracted from the whole-cell region to define the cytoplasm.Mean fluorescence intensity of the dsDNA signal was then measured in the cytoplasmic compartment.To determine the percentage of cytoplasmic dsDNA-positive cells, dsDNA speckles were enhanced to enable identification as primary objects.The resulting objects were filtered based on mean fluorescence intensity and to improve specificity, cells with at least 10 dsDNA foci were classified as positive for cytoplasmic dsDNA.Identification of the nucleus and consequently the whole cell boundary was reliant on DAPI intensity.As DNase I treatment abolished the DAPI signal, quantification of cytoplasmic intensity could not be performed for DNase I-treated conditions.Five fields of view were analysed per condition.

Wound healing assay
WT and STING1 KO HMC3 cells were pre-treated with 10 nM AZD1390 or DMSO as a control for 72 h, then seeded at a density of 79 000 cells / cm 2 into 2-well culture inserts (Ibidi).After 24 h, inserts were removed leaving a 500 μM gap, cells were washed twice in PBS then placed in DMEM supplemented with 0.5% HI-FBS to limit proliferation.Wounds were imaged every 4 h over a period of 24 h on a Lumascope LS720 (Etaluma Inc) using a 4 × phasecontrast objective.Wound closure was analysed in ImageJ and wound area is presented as a percentage of the 0-h time point.

xCELLigence chemotaxis assay
For preparation of conditioned medium, WT and STING1 KO HMC3 cells were pre-treated with 10 nM AZD1390 or DMSO as a control for 72 h, then seeded at a density of 21 000 cells / cm 2 in 6-well plates.After 48 h, cells were washed in PBS and placed in DMEM supplemented with 0.5% (v / v) HI-FBS.Conditioned medium on day 5 was centrifuged at 400 g for 10 min to remove whole cells and debris.
Chemotaxis assays were performed using Real-Time Cell Analysis (R TC A) CIM-16 plates (Agilent).The lower chamber contained conditioned medium as the chemoattractant or DMEM supplemented with 0.5% (v / v) HI-FBS as a negative control.The upper chamber was filled with 0.5% (v / v) HI-FBS and plates were left to equilibrate at 37ºC for 1 h.Background impedance (Cell Index) was measured followed by seeding 25 000 cells per well in the upper chamber in technical triplicates.Cells were left to settle at RT for 30 min, then impedance was measured every 15 min for 6 h using an xCELLigence R TC A DP instrument (Agilent).Due to the nature of the assay, absolute Cell Index values differed between independent experiments precluding presentation of the summarised data.

Statistical analysis
Statistical analysis was performed using GraphPad Prism version 9.4.1.Quantitative data is presented as mean ± standard deviation (SD) from at least three independent experiments unless stated otherwise.Normality was assessed using Q-Q plots and the Shapiro-Wilk normality test.Student's or W elch' s t -tests were used to compare means of two groups with equal or unequal variance, respectively.For comparison of three or more groups, one-or two-way ANOVAs were used.P -values ≤0.05 were deemed to be statistically significant.

Loss of ATM function in human microglia-derived cells drives STING pathway activation and a type I interferon response
Individuals with classical A-T phenotypes typically possess nonsense mutations leading to complete loss of functional protein, STING signalling was therefore investigated in two monoclonal lines of ATM KO human C20 microglia-like cells ( 28 ,48 ).Loss of ATM function was confirmed by the lack of phosphorylation of the ATM substrate CHK2 T68 in response to camptothecin (CPT), a topoisomerase I inhibitor known to induce ATM activation ( Supplementary Figure S1 A, B) ( 49 ).Increased phosphorylation of STING S366, TBK1 S172 and IRF3 S396, and upregulation of the interferon-responsive transcription factor ST A T1, indicated that the STING pathway is activated in both ATM KO C20 lines (Figure 1 A).Importantly, basal expression of IFNB1 and the ISG IFIT2 was induced in ATM KO cells, however, the induction in response to stimulation with the non-cyclic dinucleotide STING agonist, diABZI ( 50 ), was comparable to WT cells (Figure 1 B).
To confirm whether loss of kinase activity induces phenotypes similar to loss of ATM protein, human microgliaderived HMC3 cells were treated with a selective ATM kinase inhibitor AZD1390 (ATMi) ( 51 ).ATMi treatment blocked ATM auto-phosphorylation at S1981 and phosphorylation of CHK2 T68 in response to CPT, confirming successful kinase inhibition ( Supplementary Figure S1 C, D).ATMi also progres-sively increased levels of the DSB marker γH2AX, indicating accumulation of DNA damage ( Supplementary Figure S1 E, F).ATMi treatment led to a gradual increase in phosphorylation of STING, TBK1 and IRF3 between 3 and 9 days of treatment, and a concomitant upregulation of STING protein which at day 6, could be attributed to increased STING1 transcription (Figure 1 C and Supplementary Figure S1 G).ATMi also induced nuclear translocation of IRF3 in a fraction of cells similar to that seen in diABZI-treated cells (Figure 1 D, E).A low percentage of cells with nuclear IRF3 likely reflects that it can be difficult to detect owing to transient relocalisation ( 52 ).Furthermore, ATM inhibition resulted in increased expression of the type I interferon, IFNB1 , which was exacerbated upon stimulation with diABZI in ATMi-treated compared to control-treated HMC3 cells (Figure 1 F).Different responses of ATMi-treated and ATM KO cells to additional stimulation with diABZI may reflect adaptation mechanisms following constitutive loss of ATM, compared to the shortterm loss of function upon kinase inhibition.Taken together, these data confirm that loss of ATM function leads to activation of STING and a type I interferon response in human microglia-like cells.

Loss of ATM function leads to cGAS accumulation at micronuclei
Micronuclei are a hallmark of genome instability known to induce cGAS-STING activation in proliferating cells ( 9 ,10 ).Although microglial turnover is low in the healthy CNS, microglial proliferation can be stimulated in response to perturbations in their microenvironment.For example, rapid expansion of the population of microglia is observed following their depletion with CSF1R inhibitors in mice and in mouse models of neurodegenerative prion disease ( 53 ,54 ).Moreover, cell cycle genes are upregulated in cerebellar microglia in A-T, suggesting an increase in proliferative capacity ( 31 ).
To confirm that loss of ATM function induces the formation of micronuclei, human microglia-like HMC3 cells were treated with ATMi for 6 days followed by drug washout for 4 days (Figure 2 A).As expected, loss of ATM activity led to a significant increase in micronucleated cells, which was rescued by inhibitor washout (Figure 2 B, C).Similarly, ATM KO C20 lines displayed an increased micronuclei frequency compared to WT cells (Figure 2D, E).This increase was less marked than that seen with kinase inhibition, likely due to the exacerbated genome instability caused by loss of kinase activity relative to loss of ATM protein ( 55 ,56 ).
Since cGAS can accumulate at micronuclei following micronuclear envelope collapse ( 9 ,10 ), its localisation was determined in ATMi-treated HMC3 cells by immunofluorescence using a cGAS-specific antibody (Figure 2 F and Supplementary Figure S2 A).The total number of micronuclei, and within that cGAS-positive micronuclei, significantly increased upon ATMi treatment as compared to control (Figure 2 G).Similar results were seen in ATM KO C20 lines, confirming that cGAS accumulates at micronuclei in ATM-deficient human microglia-like cells (Figure 2 H).However, the proportion of cGAS-positive versus cGAS-negative micronuclei remained unchanged, indicating that loss of ATM function does not alter the propensity for micronuclear envelope collapse or cGAS recruitment ( Supplementary Figure S2 B, C).Collectively, these data confirm that micronuclei are a source of cytosolic DNA in ATM-deficient microglia-like cells.ATM loss reportedly induces accumulation of cytosolic DNA fragments, excessive formation of R-loops, and leakage of mtDNA in some cell types ( 6 , 25 , 33 , 35 , 57 , 58 ).cGAS activity is most potently stimulated by dsDNA in comparison with single-stranded DNA and RNA:DNA hybrids ( 59-62 ), therefore dsDNA localisation was visualised in ATMitreated HMC3 cells by immunofluorescence confocal microscopy.Co-staining for the mitochondrial marker TOM20 confirmed that cytosolic dsDNA did not localise to the mitochondria, and loss of dsDNA signal following DNase I treatment confirmed antibody specificity.However, no increase in cytosolic dsDNA was observed upon ATM inhibition ( Supplementary Figure S2 D and E).One reported mechanism of mtDNA leakage in ATM-deficient murine cancer cells is via downregulation of the mitochondrial transcription factor A (TF AM) ( 33 ).However, TF AM mRNA levels were unchanged in ATMi-treated HMC3 cells, consistent with reports in Atmdeficient mouse thymocytes ( Supplementary Figure S2 F) ( 63 ).
These results indicate that cGAS-STING activation likely originates primarily from micronuclei formation.
To address the requirement for cell cycle progression in activating STING, mitotic entry was blocked using the CDK1 inhibitor (CDK1i) RO-3306 in the absence or presence of ATMi.Cells were treated with ATMi for 6 days, with addition of CDK1i for the final 24 h ( Supplementary Figure S3 A).Immunoblotting and cell cycle analysis confirmed effective ATM inhibition and synchronisation of HMC3 cells in G2 phase upon CDK1i treatment ( Supplementary Figure S3 B,  C).ATMi-induced phosphorylation of STING and IRF3 and increased expression of ST A T1 were alleviated by CDK1i treatment, confirming a requirement for mitotic progression ( Supplementary Figure S3 D).
A similar experimental approach was utilised to assess whether transcription-associated DNA damage, such as that arising from R-loops ( 64 ), contributes to STING pathway activation.ATMi-treated HMC3 cells were cultured in the presence of DRB, triptolide or α-amanitin, which inhibit transcription elongation or initiation ( 65 ), for 24 h ( Supplementary Figure S3 E).Loss of RNA polymerase II (POLR2A) expression confirmed successful inhibition of transcription.We did not observe a substantial increase in apoptosis as indicated by the levels of cleaved caspase-3 following ATMi and transcription inhibition.Although phosphorylation of STING, TBK1, and IRF3 were alleviated upon transcription inhibition in ATMi-treated cells, this could, at least in part, be a consequence of TBK1 downregulation ( Supplementary Figure S3 F, G).Due to these confounding effects, the role of transcription-mediated DNA damage in STING pathway activation is presently unclear and warrants further investigation.
Additionally, the contribution of oxidative stress was assessed by culturing ATMi-treated microglia-like cells in the presence of scavengers of reactive oxygen species, including tiron, N -acetyl-l -cysteine (NAC; also enhances cellular cysteine pool), or extracellular catalase ( 66-68 ) ( Supplementary Figure S3 E, F).These treatments did not prevent STING pathway activation in ATMi-treated cells, indicating that cytosolic DNA in this experimental system is unlikely to arise from oxidative stress.These results are consistent with our previous observations that ROS scavengers failed to rescue increased phagocytosis of ATM KO microglia-like cells ( 28 ).
Taken together, these data indicate that loss of ATM function in proliferating microglia leads to recognition of micronuclei by cGAS, providing a source of sterile STING-dependent inflammation.

cGAS dependency of STING activation
STING activation can occur through mechanisms independent of cGAS and cytosolic DNA, such as inappropriate trafficking to the Golgi or via nuclear signalling upon sensing of DNA damage by PARP1 ( 69 ,70 ).Furthermore, ATM inhibition was reported to activate TBK1 in a cGAS-STINGindependent manner via SRC kinase in pancreatic cancer cells ( 34 ).
To confirm whether interferon signalling is activated via canonical cytosolic DNA sensing, cGAS and STING were depleted using siRNA in ATMi-treated HMC3 microglia.Knockdown (KD) of cGAS abolished phosphorylation of STING following ATMi treatment, while KD of cGAS or STING abolished TBK1 phosphorylation (Figure 3 A-B).Biochemical fractionation revealed that nuclear translocation of phosphorylated IRF3 and ST A T1 in A TMi-treated cells was attenuated upon cGAS or STING KD (Figure 3 C, D).Importantly, an increase in expression of IFNB1 and IFIT2 in ATMitreated cells is prevented upon cGAS or STING KD, while induction of IL6 is only partially dependent on cGAS and STING (Figure 3 E).As IL6 is a target of NF-κB transcription factors, and we previously reported activation of noncanonical NF-κB upon loss of ATM function, residual inflammatory signalling upon cGAS-STING deletion may be driven by this pathway ( 28 ).
Taken together, these data demonstrate that canonical cGAS-STING signalling drives the type I interferon response in ATM-deficient microglia-derived cells.
Type I interferon signalling elicits chemokine and motility transcriptional programmes in human iPSC-derived microglia STING signalling has been linked with activation of NF-κB signalling and induction of senescence programmes in Atmdeficient murine microglia and A-T brain organoids ( 25 ,32 ).However, type I interferon is a major arm of transcriptional responses downstream of mammalian STING ( 71 ).To determine how type I interferon shapes microglial function, bulk RNAseq was performed in human iPSC-derived iCell microglia treated with human IFNβ for 6 or 24 h (Figure 4 A).As expected, differentially expressed genes (DEGs) in IFNβtreated iPSC-derived microglia are enriched in gene ontology (GO) biological processes associated with antiviral immunity, including positive regulation of immune response, response to virus and positive regulation of inflammatory response (Figure 4 B).Importantly, GO terms associated with cell locomotion, motility and migration were among the top 5 enriched processes.Processes linked with actin filament organisation, cell polarity and cell shape also featured in the top 20 enriched GO processes.
The chemokine superfamily is divided into C, CC, CXC and CX3C subtypes based on the amino acid arrangement between conserved N-terminal cysteine residues.Chemokines signal via transmembrane G-protein coupled receptors (GPCRs) to regulate cell polarity, cytoskeletal organisation and adhesion, driving cell recruitment along a chemotactic gradient ( 72 ).Protein interaction network analysis at 6 and 24 h identified a significant cluster of chemokines and their receptors, indicating enrichment of microglial chemokine signalling following IFNβ treatment (Figure 4 C).Specifically, CXCL9 , CXCL10 and CXCL11, ligands of the CXCR3 receptor, and CCL8 , a ligand of CCR2, are among the top upregulated chemokines upon IFNβ treatment at both 6 and 24 h (Figure 4 D and Supplementary Table S3 ).In addition, CCL5 among other chemokines of the CC family, is highly upregulated (Figure 4 C, D).Therefore, chemokine signalling is a critical outcome of type I interferon responses in human microglial cells.

ATM loss drives STING-dependent chemokine production in microglia-derived cells
Given the induction of chemokine and cell motility programmes in response to IFNβ treatment in iPSC-derived microglia, we sought to investigate whether ATM loss induces microglial chemokine production and whether this could be  STING-dependent.Single-cell RNAseq previously identified Cxcl10 and Ccl5 as signature ISGs induced specifically in micronucleated cells ( 10 ), therefore mRNA levels of these chemokines were assessed in ATM-deficient microglia-like cells.CCL5 and CXCL10 were found to be significantly upregulated in ATM KO C20 cells and induced by STING activation with diABZI (Figure 5 A).As siRNA delivery and lipofection can activate the innate immune system ( 73 ,74 ), STING1 KO HMC3 cells were established to further investigate the consequences of chronic STING activation on microglial function.In two monoclonal STING1 KO lines, TBK1 S172 and IRF3 S396 phosphorylation was abolished ( Supplementary Figure S4 A-B) and perinuclear STING clusters were no longer detectable in response to diABZI, confirming the lack of functional STING ( Supplementary Figure S4 C).
We therefore focused on the role of STING in chemokine production in basal conditions and upon treatment of WT and STING1 KO HMC3 cells with ATMi (Figure 5 B).As expected, the induction of IFNB1 in cells treated with ATMi or diABZI was completely abolished in STING1 KO lines ( Supplementary Figure S4 D).Although IFNB1 mRNA was induced, ATM inhibition increased secretion of IFN-α2a rather than IFNβ, and this was dependent on STING ( Supplementary Figure S4 E).This discordance between mRNA levels is likely to be attributed to the kinetics of the secretory response.Importantly, ATM inhibition also induced a robust chemokine response, evidenced by increased mRNA levels of CCL5 and CXCL10 , which were fully dependent on STING.Stimulation with diABZI similarly induced CCL5 and CXCL10 expression (Figure 5 C).Moreover, STING deletion markedly reduced CCL5 mRNA in basal conditions, and a similar tendency was observed in the case of CXCL10 , suggesting tonic, i.e. basal, STING-dependent chemokine signalling.As CXCL10 was the most strongly upregulated gene following IFNβ treatment in iPSC-derived microglia, its concentrations were measured in cell culture supernatants.ATM inhibition promoted CXCL10 secretion in a STING-dependent manner, whereas CXCL10 was not detected in supernatants from STING1 KO cells (Figure 5 D).
Given the robust chemokine response in vitro , mRNA levels of CGAS , STING1 , CCL5 and CXCL10 were determined by RT-qPCR in cerebellar homogenates from individuals with A-T and from age-and gender-matched individuals with no known diseases of the CNS (Figure 5 E-F).Confirming previous single-nucleus RNAseq data, expression of CGAS and STING1 was significantly upregulated in A-T cerebella compared to matched controls ( 31 ).Importantly, levels of CCL5 and CXCL10 were also increased in A-T brains, albeit not significantly, likely owing to genetic variability between individuals and a small sample size limited by tissue availability (Figure 5 F).Whole cerebellum gene expression changes therefore indicate upregulation of CGAS, STING1, and possibly chemokines in A-T.Taken together, these data demonstrate that STING drives production of chemokines upon loss of ATM function in human microglia-like cells with potential relevance in human disease.

Persistent DNA damage promotes a STING-dependent chemokine response
To investigate the role of DNA damage in STING-dependent chemokine responses, WT and STING1 KO HMC3 cells were treated with the topoisomerase II poison etoposide, the DNA synthesis inhibitor aphidicolin, and the DNA crosslinking agent mitomycin C. To model persistent low-level DNA damage, cells were treated for 6 days using low doses of drugs that did not induce cell death ( Supplementary Figure S5 A).All DNA damaging agents induced the formation of micronuclei and consequent STING activation, as evidenced by increased STING S366 and TBK1 S172 phosphorylation, which was absent in STING1 KO cells ( Supplementary Figure S5 B, C).Moreover, all three agents induced CCL5 expression, which was dependent on STING ( Supplementary Figure S5 D).These data indicate that DNA damage, rather than ATM loss per se, drives STING-dependent chemokine induction in human microglia-derived cells.

ATM inhibition drives microglial chemotaxis in a STING-dependent manner
Microglia are highly motile cells, as their processes dynamically survey their microenvironment in the absence of a stimulus, and are rapidly directed towards sites of infection or injury ( 75 ).Given that STING regulates tonic chemokine production in microglia-like cells, the role of STING in regulating basal microglial migration was investigated.To address this, a variant of the scratch-wound assay was utilised, in which cells are seeded in a well containing silicone inserts which are subsequently removed to produce a uniform cell-free gap (Figure 6 A).Live cell imaging showed that deletion of STING1 leads to delayed gap closure, indicating that STING regulates basal microglial migration (Figure 6 B, C).Furthermore, chemotactic migration of WT and STING1 KO HMC3 cells, which were grown in the presence or absence of ATM inhibitor for 6 days, was investigated using xCELLigence label-free real-time cell analysis based on measuring cellular impedance (Figure 6 D) ( 76 ).Loss of ATM activity enhanced chemotactic migration of cells towards their respective conditioned medium, and this effect was reduced in the absence of STING (Figure 6 E).
Overall, these data demonstrate that STING regulates chemotaxis of microglia-derived cells in basal conditions and following loss of ATM function.

Discussion
In this study, we utilised A-T as a model genome instability disorder to explore how cGAS-STING signalling regulates microglial function upon persistent DNA damage.Consistent with previous observations upon ATM deletion or pharmacological inhibition, we find that the cGAS-STING pathway induces chronic inflammation following ATM loss in models of human microglia-derived cells ( 6 , 25 , 32 , 35 ).Both genomic and mitochondrial origins of cytosolic DNA in ATM deficiency have previously been proposed ( 12 , 33 , 35 ).Whilst a mitochondrial origin cannot be ruled out in the present work, we find that STING signalling in the absence of ATM is associated with cGAS activation by micronuclei in proliferating microglia (Figure 7 ).Indeed, ATM-deficient cells present with chromosomal rearrangements that form upon nonhomologous end joining of single-ended DSBs and could drive micronucleus formation ( 77 ).Evidently, STING-dependent inflammation is phenocopied upon prolonged treatment of ATM-proficient microglia-derived cells with a range of DNA damaging agents, all of which could potentiate the formation of DSBs and consequently micronuclei.These observations argue against a specific effect of ATM loss as a driver of STING   activation in microglia.We therefore propose that chronic inflammation in ATM deficiency is driven by genome instability, consistent with the nuclear origin of cytosolic DNA upon Atm inhibition in murine microglia ( 12 ).Whilst the possibility that transcription-mediated DNA damage contributes to cGAS activation cannot be excluded, we find that oxidative DNA damage does not appear to drive STING pathway activation upon ATM loss.
Micronuclei are a hallmark of genome instability, raising the question of whether STING-dependent neuroinflammation is common among inherited disorders associated with a defective DNA damage response.Not all genome instability disorders present with neuropathology, indicating that proinflammatory signalling may depend on the initiating DNA lesion.Nuclear chromatin architecture and its inheritance by micronuclei can influence cGAS recruitment to micronuclei following genotoxic stress ( 11 ).Differential effects on chromatin organisation and the consequences for cytosolic DNA species may therefore regulate the extent of proinflammatory signalling and neuropathology in DNA repair deficits.
As micronuclei form during mitosis, the cellular proliferative capacity will also dictate the rate of micronuclei formation.Importantly, microglial proliferation is highly responsive to external cues, including inflammation, and expansion of the microglial compartment is frequently observed in neurodegenerative disease ( 53 ,78 ).It is therefore possible that microglial proliferation is stimulated by perturbations in the CNS microenvironment during genome instability, perpetuating neuroinflammatory processes.Consistent with this, mi-crogliosis is observed in the spinal cord of Atm-deficient rats and several studies have highlighted increased turnover of cerebellar microglia relative to cortical microglia, suggesting a region-specific increase in microglial proliferative capacity ( 24 , 30 , 31 ).
Previous studies established a connection between genome instability, activation of STING, and inflammation in ATM deficiency ( 12 , 25 , 32 , 35 ).We extend these findings by demonstrating that interferon responses to ATM inhibition are abolished in STING-deficient cells, however, the consequences of type I interferon production on microglial homeostasis are unclear.We therefore focus on investigating interferondependent regulation of microglial function.Consistent with IFNα administration in murine microglia, we discover that IFNβ potently upregulates signalling networks associated with chemotaxis and migration in human iPSC-derived microglia ( 79 ,80 ).These data identify chemotactic responses as a key outcome of type I interferon signalling.Indeed, STING signalling induces production of chemokines, such as CCL5 and CXCL10 , in human microglia-like cells upon ATM loss or persistent DNA damage (Figure 7 ).Whilst acute chemotactic responses are critical for antimicrobial immunity, excessive and / or chronic production of chemokines is implicated in detrimental microglial functions in vivo .For example, CX CL10-CX CR3 signalling regulates microglial recruitment and dendritic loss following axonal injury ( 81 ).Moreover, microglia-derived CCL3 / 4 / 5 activates neuronal CCR5, leading to autophagy inhibition and accumulation of protein aggregates in mouse models of Huntington's disease and tauopathy ( 82 ).Interestingly, CCR5 also promotes microglial recruitment to cerebral vasculature to support the blood brain barrier (BBB) during acute inflammation, however, chronic inflammation drives BBB dysfunction via microglial phagocytosis of astrocytic end feet ( 83 ).Sustained, excessive chemokine production may therefore shift the balance towards eliciting deleterious effects on neuronal function and the CNS microenvironment.As chemokines are implicated in recruitment of peripheral immune cells, the question of whether cGAS-STING signalling drives immune infiltration during chronic CNS inflammation in A-T warrants further investigation ( 84 ).
Importantly, this study identifies STING as a regulator of microglial chemotaxis, both in basal conditions and during ATM deficiency (Figure 7 ).In mice, STING activation mediates chemotactic recruitment of T-cells into the inflamed peritoneum and tumour-infiltrating neutrophils ( 85 ,86 ).Conversely, STING activation supresses migration of cancer cells and tumour-infiltrating neutrophils by reducing translation of the matrix-remodelling serine peptidase PLAU ( 87 ).However, knowledge of whether STING regulates microglial migration is lacking.We find that STING-deficient microglia-like cells display a marked defect in migration in the absence of stimulation.Whilst STING may act intrinsically to regulate cytoskeletal dynamics, it is possible that tonic chemokine signalling underlies this phenotype, as STING loss reduced basal chemokine expression.Previous work identified enhanced migration in Atm-deficient primary murine microglia and astrocytes isolated from the cerebellum, but not the cerebral cortex ( 26 ).This indicates cerebellum-specific effects of ATM loss on microglial migration may exist, and we propose that STING signalling may underlie this process.In addition, the Rho family of small GTPases coordinate actin cytoskeleton dynamics during cell migration.In ATM-deficient human fibroblasts, oxidative stress reportedly promotes increased migration by activating the Rho GTPase Rac1, suggesting that oxidative stress may also factor into regulation of cell migration upon ATM loss ( 88 ).
Microglial soma are largely immobilised during baseline microglial motility in vivo , however, their processes are highly motile enabling constant surveillance of the local parenchyma.In response to focal brain injury, microglial processes are rapidly directed towards the injured site along an ATP gradient ( 75 ,89 ).Uniquely, cerebellar microglia exhibit baseline soma motility and frequently interact with Purkinje cell soma and dendrites; cerebellar microglia may therefore respond differently to chemokines ( 90 ).Enhanced sampling of the surrounding parenchyma may also improve scavenging of apoptotic cells or debris and detection of pathogenic stimuli, promoting beneficial outcomes in an acute setting.Conversely, increased surveillance in the degenerating brain could amplify recognition of neuronal stress, including via chemotaxisdriven clustering of activated microglia, which might potentiate detrimental functions of microglia.For example, we previously showed that ATM-deficient microglia form clusters which damage neurons in vitro through aberrant engulfment ( 28 ).Finally, cytoskeletal reorganisation required for sustained chemotaxis is energetically expensive and may drive metabolic reprogramming and microglial dysfunction.
In conclusion, this study identifies cytosolic DNA sensing as a critical mechanism regulating microglial motility and chemotaxis in health and disease.Given the expanding roles of cGAS-STING signalling in neurodegeneration ( 91 ), our study uncovers mechanistic insights into inflammatory mechanisms not just in A-T, but more broadly in neurological diseases associated with genome instability and excessive interferon production in the CNS.Given the co-occurring immunodeficiency, blockade of STING signalling may be contraindicated in A-T .However , targeting the accumulation of cytosolic DNA species or identifying specific downstream regulators of neurological phenotypes may provide therapeutic benefit.This work provides a rationale for exploring modulators of cytosolic DNA sensing as a potential therapeutic strategy to alleviate neurological decline in A-T and similar genome instability disorders.

50 Figure 1 .
Figure 1.Loss of ATM function in human microglia-derived cells drives STING pathway activation and a type I interferon response.( A ) Representative immunoblot of STING pathway activation in ATM KO C20 cells (clones #1 and #2).Loading control: Vinculin.Quantification of phosphorylated proteins and ST A T1 is relativ e to respectiv e total proteins and vinculin, respectiv ely, and normalised to WT. ( B ) R elativ e mRNA le v els of IFNB1 and IFI T2 in WT and ATM KO C20 cells treated with 1 μM STING agonist diABZI, or DMSO as control, for 5 h.C q values normalised to IPO8 and DMSO-treated WT cells.Mean log 2 fold change ± SD ( n = 3).Two-way ANO V A with Tukey's post-hoc comparison test.( C ) Representative immunoblot of HMC3 cells treated with 10 nM ATM inhibitor AZD1390 (ATMi), or DMSO as control, for 1, 3, 6 or 9 da y s.L oading control: Vinculin.NS: nonspecific.Quantification of phosphorylated proteins is relative to respective total proteins and normalised to Day 1 DMSO control.( D ) Representative images of IRF3 localisation in HMC3 cells stimulated for 2 h with 1 μM diABZI, or DMSO as control, or with 10 nM ATMi or DMSO for 6 da y s (diABZI and ATMi stimulation are part of separate experiments).Red: IRF3, cyan: DNA (DAPI).20x magnification, scale bar = 25 μm.Yellow arrows indicate cells with nuclear IRF3.( E ) Percentage of cells with nuclear translocation of IRF3 treated as in ( D ).Mean ± SD (n = 3).Unpaired, two-tailed Student's t -tests.Dashed line indicates two separate experiments.( F ) Relative IFNB1 mRNA levels in HMC3 cells treated with ATMi or DMSO for 6 days followed by 1 μM diABZI, or DMSO as a control, for 5 h.C q values normalised to RPS13 and DMSO-treated cells.Mean log 2 fold change ± SD (n = 3).Two-way ANO V A with Tukey's post-hoc comparison test.* P ≤ 0.05; ** P ≤ 0.01; *** P ≤ 0.001; **** P ≤ 0.0 0 01; ns = not significant.

2 Figure 2 .
Figure 2. Loss of ATM function leads to cGAS accumulation at micronuclei.( A ) Representative immunoblot of HMC3 cells treated with 10 nM AZD1390 (ATMi), or DMSO as a control, for 6 days followed by 4-day ATMi washout.To confirm ATM inhibition, cells were treated with 1 μM camptothecin (CPT) or DMSO as a control for 1 h.Loading control: GAPDH.Quantification of ATM pS1981 and CHK2 pT68 is relative to respective total proteins and normalised to Day 6 DMSO control.( B ) Representative images of micronuclei (MN) in HMC3 cells treated as in (A).Yellow arrows indicate MN visualised by DAPI st aining .20x magnification, scale bar = 15 μm.( C ) Quantification of MN frequency as in ( B ). Mean ± SD ( n = 3).Tw o-w a y ANO V A with Tuk e y's post-hoc comparison test.( D ) R epresentativ e images of MN in WT and ATM KO C20 cells.Yellow arrows indicate MN visualised by DAPI st aining .20x magnification, scale bar = 15 μm.( E ) Quantification of MN frequency as in ( D ).Mean ± SD (n = 4).One-w a y ANO V A with Tuk e y's post-hoc comparison test.( F ) R epresentativ e images of MN negative (cGAS − MN) or positive (cGAS + MN) for cGA S .Yellow arrows indicate MN.Blue: DAPI, green: cGA S .20x magnification, scale bar = 15 μm.( G ) Quantification of cGAS + and cGAS − MN in HMC3 cells treated with ATMi or DMSO for 6 days.MN frequency per cell is shown.Mean ± SD ( n = 3).Two-way ANO V A with Tukey's post-hoc comparison test.( H ) Quantification of cGAS + and cGAS − MN in WT and ATM KO C20 cells.MN frequency per cell is shown.Mean ± SD ( n = 3).Two-way ANO V A with Tukey's post-hoc comparison test.* P ≤ 0.05; **** P ≤ 0.0 0 01; ns = not significant.

Figure 3 .
Figure 3. S TING activ ation and type I interferon signalling in ATM deficiency are dependent on cGA S .( A ) R epresentativ e immunoblot of siRNA-mediated cGAS and STING depletion in HMC3 cells treated with 10 nM ATMi, or DMSO as a control, for 6 days.Positive control: 7 μM 2 ,3 -cGAMP for 1.5 h deliv ered b y digitonin permeabilization, mock: digitonin permeabilization.L oading control: α/ β-tubulin.NS: nonspecific.( B ) R elativ e quantification of TBK1 pS172 as in (A) normalised to total protein and DMSO-and control (Ctrl) siRNA-treated cells.Mean ± SD ( n = 3, e x cept 2 ,3 -cGAMP treatment where n = 2).Tw o-w a y ANO V A with Tuk e y's post-hoc comparison test.( C ) R epresentativ e immunoblot of IRF3 pS396 and S T A T1 pY701 le v els in cytosolic and nuclear extracts of HMC3 cells as in (A).Cytoplasmic marker: GAPDH; nuclear marker: fibrillarin.( D ) Relative quantification of IRF3 pS396 and ST A T1 pY701 in nuclear extracts as in ( B ) normalised to fibrillarin and DMSO-and Ctrl siRNA-treated cells.Mean ± SD ( n = 3).Two-way ANO V A with Tuk e y's post-hoc comparison test.( E ) R elativ e mRNA le v els of IFNB1 , IFIT2 , and IL6 of cells as in (A).C q values normalised to RPS13 of cells treated with control (Ctrl) siRNA and DMSO.Mean log 2 fold change ± SD ( n = 3).Two-way ANO V A with Tukey's post-hoc comparison test.* P ≤ 0.05; ** P ≤ 0.01; *** P ≤ 0.001; **** P ≤ 0.0 0 01; ns = not significant.

Figure 4 .
Figure 4. Migration-related pathw a y s and chemotaxis genes are enriched in iPSC-derived microglia stimulated with IFN-β.( A ) Schematic of e xperimental w orkflo w. iCell microglia w ere treated with v ehicle or 5 ng / ml human IFN-β (hIFN-β) f or 6 or 24 h ( n = 3), f ollo w ed b y bulk RNAseq.( B ) Dotplot of top 20 GO biological processes enriched among differentially expressed genes (DEGs) in IFN-β-treated iCell microglia.Migration-related processes highlighted in teal.( C ) STRING network analysis of significantly differentially expressed genes (adjusted P -value < 0.05) related to cell chemotaxis at 6 and 24 h of IFN-β-treated compared to vehicle-treated cells.Colour scale represents log 2 fold change (Log2FC).( D ) Heatmap shows gene expression changes (Log 2 FC) of significantly differentially expressed chemokine family genes in cells treated as in (A).Grey indicates the genes that are not significantly differentially expressed (adjusted P -value > 0.05).

Figure 5 .
Figure 5. Loss of ATM function leads to STING-dependent chemokine secretion.( A ) R elativ e mRNA le v els of CCL5 and CXCL10 in WT and ATM KO C20 cells and upon treatment with 1 μM diABZI, or DMSO as control, for 5 h.C q values normalised to IPO8 and DMSO-treated WT cells.Mean log 2 fold change ± SD ( n = 3).Tw o-w a y ANO V A with Tuk e y's post-hoc comparison test.( B ) Schematic of experimental workflow.WT and STING1 KO HMC3 cells were treated with 10 nM ATMi, or DMSO as a control, for 6 days.mRNA levels were measured by RT-qPCR.Secretion was measured 24 h after media change to low FBS supplemented with 1 μM diABZI, or DMSO as a control.( C ) Relative mRNA levels of CCL5 and CXCL10 from cells treated as in (B).

Figure 6 .Figure 7 .
Figure 6.STING regulates microglial chemotaxis.( A ) Schematic of experimental workflow for wound healing migration assay.( B ) Representative phase contrast microscopy images of gap area at 0 and 24 h in WT and STING1 KO HMC3 cells.4x magnification, scale bar = 250 μm. ( C ) Normalised gap area expressed as a percentage of gap area at 0 h.Mean ± SD (n = 3).Area under curve analysed using one-way ANO V A with Tukey's post-hoc comparison test.( D ) Schematic of experimental workflow for xCELLigence chemotaxis assay.WT and STING1 KO HMC3 cells were treated with 10 nM ATMi, or DMSO as a control, for 6 days.Chemotactic migration towards the respective conditioned medium was measured.( E ) Kinetics of microglial chemotaxis of cells as in (D).Mean ± SD ( n = 3 technical replicates).R epresentativ e of 3 independent experiments.Two-way ANO V A with Tukey's post-hoc comparison test.** P ≤ 0.01; **** P ≤ 0.0 0 01.