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Mouse Anti-ATF4 Recombinant Antibody (2B3) (CBMAB-A3871-YC)

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Summary

Host Animal
Mouse
Specificity
Human
Clone
2B3
Antibody Isotype
IgG1, κ
Application
ELISA, IF, WB

Basic Information

Immunogen
Partial recombinant protein corresponding to aa171-270, of human ATF4 with GST tag (NP_001666).
Specificity
Human
Antibody Isotype
IgG1, κ
Clonality
Monoclonal
Application Notes
The COA includes recommended starting dilutions, optimal dilutions should be determined by the end user.
ApplicationNote
IF(ICC)10 µg/ml

Formulations & Storage [For reference only, actual COA shall prevail!]

Format
Liquid
Buffer
PBS, pH 7.4
Preservative
None
Concentration
Batch dependent
Storage
Store at 4°C short term (1-2 weeks). Aliquot and store at -20°C long term. Avoid repeated freeze/thaw cycles.

Target

Full Name
Activating Transcription Factor 4
Introduction
ATF4 is a transcription factor that was originally identified as a widely expressed mammalian DNA binding protein that could bind a tax-responsive enhancer element in the LTR of HTLV-1. ATF4 was also isolated and characterized as the cAMP-response element
Entrez Gene ID
UniProt ID
Alternative Names
Activating Transcription Factor 4; Tax-Responsive Enhancer Element-Binding Protein 67; Cyclic AMP-Responsive Element-Binding Protein 2; CAMP-Responsive Element-Binding Protein 2; CAMP-Dependent Transcription Factor ATF-4; Tax-Responsive Enhancer Element B
Function
Transcription factor that binds the cAMP response element (CRE) (consensus: 5'-GTGACGT[AC][AG]-3') and displays two biological functions, as regulator of metabolic and redox processes under normal cellular conditions, and as master transcription factor during integrated stress response (ISR) (PubMed:17684156, PubMed:16682973, PubMed:31444471, PubMed:32132707).
Binds to asymmetric CRE's as a heterodimer and to palindromic CRE's as a homodimer (By similarity).
Core effector of the ISR, which is required for adaptation to various stress such as endoplasmic reticulum (ER) stress, amino acid starvation, mitochondrial stress or oxidative stress (PubMed:32132707).
During ISR, ATF4 translation is induced via an alternative ribosome translation re-initiation mechanism in response to EIF2S1/eIF-2-alpha phosphorylation, and stress-induced ATF4 acts as a master transcription factor of stress-responsive genes in order to promote cell recovery (PubMed:32132706, PubMed:32132707).
Promotes the transcription of genes linked to amino acid sufficiency and resistance to oxidative stress to protect cells against metabolic consequences of ER oxidation (By similarity).
Activates the transcription of NLRP1, possibly in concert with other factors in response to ER stress (PubMed:26086088).
Activates the transcription of asparagine synthetase (ASNS) in response to amino acid deprivation or ER stress (PubMed:11960987).
However, when associated with DDIT3/CHOP, the transcriptional activation of the ASNS gene is inhibited in response to amino acid deprivation (PubMed:18940792).
Together with DDIT3/CHOP, mediates programmed cell death by promoting the expression of genes involved in cellular amino acid metabolic processes, mRNA translation and the terminal unfolded protein response (terminal UPR), a cellular response that elicits programmed cell death when ER stress is prolonged and unresolved (By similarity).
Together with DDIT3/CHOP, activates the transcription of the IRS-regulator TRIB3 and promotes ER stress-induced neuronal cell death by regulating the expression of BBC3/PUMA in response to ER stress (PubMed:15775988).
May cooperate with the UPR transcriptional regulator QRICH1 to regulate ER protein homeostasis which is critical for cell viability in response to ER stress (PubMed:33384352).
In the absence of stress, ATF4 translation is at low levels and it is required for normal metabolic processes such as embryonic lens formation, fetal liver hematopoiesis, bone development and synaptic plasticity (By similarity).
Acts as a regulator of osteoblast differentiation in response to phosphorylation by RPS6KA3/RSK2: phosphorylation in osteoblasts enhances transactivation activity and promotes expression of osteoblast-specific genes and post-transcriptionally regulates the synthesis of Type I collagen, the main constituent of the bone matrix (PubMed:15109498).
Cooperates with FOXO1 in osteoblasts to regulate glucose homeostasis through suppression of beta-cell production and decrease in insulin production (By similarity).
Activates transcription of SIRT4 (By similarity).
Regulates the circadian expression of the core clock component PER2 and the serotonin transporter SLC6A4 (By similarity).
Binds in a circadian time-dependent manner to the cAMP response elements (CRE) in the SLC6A4 and PER2 promoters and periodically activates the transcription of these genes (By similarity).
Mainly acts as a transcriptional activator in cellular stress adaptation, but it can also act as a transcriptional repressor: acts as a regulator of synaptic plasticity by repressing transcription, thereby inhibiting induction and maintenance of long-term memory (By similarity).
Regulates synaptic functions via interaction with DISC1 in neurons, which inhibits ATF4 transcription factor activity by disrupting ATF4 dimerization and DNA-binding (PubMed:31444471).
(Microbial infection) Binds to a Tax-responsive enhancer element in the long terminal repeat of HTLV-I.
Biological Process
Bone mineralization Source: UniProtKB
Cellular calcium ion homeostasis Source: Ensembl
Cellular response to amino acid starvation Source: UniProtKB
Cellular response to dopamine Source: CAFA
Cellular response to glucose starvation Source: ParkinsonsUK-UCL
Cellular response to oxidative stress Source: UniProtKB
Cellular response to oxygen-glucose deprivation Source: Ensembl
Cellular response to UV Source: UniProtKB
Circadian regulation of gene expression Source: UniProtKB
Embryonic hemopoiesis Source: UniProtKB
Endoplasmic reticulum unfolded protein response Source: UniProtKB
Gamma-aminobutyric acid signaling pathway Source: Ensembl
Gluconeogenesis Source: UniProtKB
HRI-mediated signaling Source: UniProtKB
Integrated stress response signaling Source: UniProtKB
Intrinsic apoptotic signaling pathway in response to endoplasmic reticulum stress Source: UniProtKB
L-asparagine metabolic process Source: UniProtKB
Lens fiber cell morphogenesis Source: UniProtKB
mRNA transcription by RNA polymerase II Source: UniProtKB
Negative regulation of cold-induced thermogenesis Source: YuBioLab
Negative regulation of oxidative stress-induced neuron death Source: ParkinsonsUK-UCL
Negative regulation of potassium ion transport Source: Ensembl
Negative regulation of transcription by RNA polymerase II Source: UniProtKB
Negative regulation of translational initiation in response to stress Source: UniProtKB
Neuron differentiation Source: Ensembl
PERK-mediated unfolded protein response Source: UniProtKB
Positive regulation of apoptotic process Source: ParkinsonsUK-UCL
Positive regulation of biomineral tissue development Source: Ensembl
Positive regulation of gene expression Source: ARUK-UCL
Positive regulation of neuron apoptotic process Source: UniProtKB
Positive regulation of sodium-dependent phosphate transport Source: Ensembl
Positive regulation of transcription, DNA-templated Source: UniProtKB
Positive regulation of transcription by RNA polymerase I Source: ParkinsonsUK-UCL
Positive regulation of transcription by RNA polymerase II Source: UniProtKB
Positive regulation of transcription from RNA polymerase II promoter in response to arsenic-containing substance Source: ParkinsonsUK-UCL
Positive regulation of transcription from RNA polymerase II promoter in response to endoplasmic reticulum stress Source: ParkinsonsUK-UCL
Positive regulation of transcription from RNA polymerase II promoter in response to oxidative stress Source: ParkinsonsUK-UCL
Positive regulation of transcription from RNA polymerase II promoter in response to stress Source: ParkinsonsUK-UCL
Positive regulation of vascular associated smooth muscle cell apoptotic process Source: Ensembl
Positive regulation of vascular endothelial growth factor production Source: ParkinsonsUK-UCL
Regulation of eIF2 alpha phosphorylation by heme Source: Reactome
Regulation of osteoblast differentiation Source: UniProtKB
Regulation of synaptic plasticity Source: UniProtKB
Regulation of transcription, DNA-templated Source: UniProtKB
Regulation of transcription by RNA polymerase II Source: GO_Central
Response to endoplasmic reticulum stress Source: UniProtKB
Response to manganese-induced endoplasmic reticulum stress Source: Ensembl
Response to nutrient levels Source: UniProtKB
Response to toxic substance Source: Ensembl
Transcription by RNA polymerase II Source: UniProtKB
Cellular Location
Nucleus; Nucleus speckle; Cytoplasm; Cell membrane; Centrosome.Colocalizes with GABBR1 in hippocampal neuron dendritic membranes (By similarity). Colocalizes with NEK6 at the centrosome (PubMed:20873783). Recruited to nuclear speckles following interaction with EP300/p300 (PubMed:16219772).
PTM
Ubiquitinated by SCF(BTRC) in response to mTORC1 signal, followed by proteasomal degradation and leading to down-regulate expression of SIRT4 (PubMed:11238952). Interaction with EP300/p300 inhibits ubiquitination by SCF(BTRC) (PubMed:16219772).
Phosphorylation at Ser-245 by RPS6KA3/RSK2 in osteoblasts enhances transactivation activity and promotes osteoblast differentiation (PubMed:15109498). Phosphorylated on the betaTrCP degron motif at Ser-219, followed by phosphorylation at Thr-213, Ser-224, Ser-231, Ser-235 and Ser-248, promoting interaction with BTRC and ubiquitination (By similarity). Phosphorylation is promoted by mTORC1 (By similarity). Phosphorylation at Ser-215 by CK2 decreases its stability (PubMed:23123191). Phosphorylated by NEK6 (PubMed:20873783).
Hydroxylated by PHD3, leading to decreased protein stability.
More Infomation

Demmings, M. D., Tennyson, E. C., Petroff, G. N., Tarnowski-Garner, H. E., & Cregan, S. P. (2021). Activating transcription factor-4 promotes neuronal death induced by Parkinson’s disease neurotoxins and α-synuclein aggregates. Cell Death & Differentiation, 28(5), 1627-1643.

Lorenz, N. I., Sittig, A. C., Urban, H., Luger, A. L., Engel, A. L., Münch, C., ... & Ronellenfitsch, M. W. (2021). Activating transcription factor 4 mediates adaptation of human glioblastoma cells to hypoxia and temozolomide. Scientific reports, 11(1), 1-11.

Ebert, S. M., Bullard, S. A., Basisty, N., Marcotte, G. R., Skopec, Z. P., Dierdorff, J. M., ... & Adams, C. M. (2020). Activating transcription factor 4 (ATF4) promotes skeletal muscle atrophy by forming a heterodimer with the transcriptional regulator C/EBPβ. Journal of Biological Chemistry, 295(9), 2787-2803.

Liu, T. H., Tao, W. C., Liang, Q. E., Tu, W. Q., Xiao, Y., & Chen, L. G. (2020). Gut microbiota-related evidence provides new insights into the association between activating transcription factor 4 and development of salt-induced hypertension in mice. Frontiers in cell and developmental biology, 8, 1283.

Mukherjee, D., Bercz, L. S., Torok, M. A., & Mace, T. A. (2020). Regulation of cellular immunity by activating transcription factor 4. Immunology Letters.

Wang, X., Han, Y., Hu, G., Guo, J., & Chen, H. (2020). Endoplasmic reticulum stress induces miR-706, a pro-cell death microRNA, in a protein kinase RNA-like ER kinase (PERK) and activating transcription factor 4 (ATF4) dependent manner. Cell Journal (Yakhteh), 22(3), 394.

Ou, L., Lan, Y., Feng, Z., Feng, L., Yang, J., Liu, Y., ... & Guo, R. (2019). Functionalization of SF/HAP Scaffold with GO-PEI-miRNA inhibitor complexes to enhance bone regeneration through activating transcription factor 4. Theranostics, 9(15), 4525.

Liu, J., Amar, F., Corona, C., So, R. W., Andrews, S. J., Nagy, P. L., ... & Greene, L. A. (2018). Brain-derived neurotrophic factor elevates activating transcription factor 4 (ATF4) in neurons and promotes ATF4-dependent induction of Sesn2. Frontiers in molecular neuroscience, 11, 62.

Corona, C., Pasini, S., Liu, J., Amar, F., Greene, L. A., & Shelanski, M. L. (2018). Activating transcription factor 4 (ATF4) regulates neuronal activity by controlling GABABR trafficking. Journal of Neuroscience, 38(27), 6102-6113.

Lai, D. W., Lin, K. H., Sheu, W. H. H., Lee, M. R., Chen, C. Y., Lee, W. J., ... & Sheu, M. L. (2017). TPL2 (therapeutic targeting tumor progression locus-2)/ATF4 (activating transcription factor-4)/SDF1α (chemokine stromal cell-derived factor-α) axis suppresses diabetic retinopathy. Circulation research, 121(6), e37-e52.

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For research use only. Not intended for any clinical use.

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