Human Cellular tumor antigen p53 (TP53) ELISA Kit (HUEB0349)
- SKU:
- HUEB0349
- Product Type:
- ELISA Kit
- Size:
- 96 Assays
- Uniprot:
- P04637
- Range:
- 0.156-10 ng/ml
- ELISA Type:
- Sandwich
- Reactivity:
- Human
Description
Human Cellular tumor antigen p53 (TP53) ELISA Kit
The Human Cellular Tumor Antigen p53 (TP53) ELISA Kit is specifically designed for the quantitative detection of TP53 levels in human serum, plasma, and cell culture supernatants. This kit offers a high level of sensitivity and specificity, ensuring accurate and reproducible results for various research applications.TP53, also known as the p53 tumor suppressor protein, is a crucial factor in regulating cell growth and division, as well as DNA repair and apoptosis. Mutations in the TP53 gene are commonly associated with various types of cancer, making it a valuable biomarker for cancer research and therapy development.
This ELISA kit provides researchers with a powerful tool for studying TP53 levels in both healthy and diseased samples, offering insights into the role of this protein in cancer development and progression. With its reliable performance and ease of use, the Human Cellular Tumor Antigen p53 (TP53) ELISA Kit is an essential resource for advancing cancer research and personalized medicine approaches.
Product Name: | Human Cellular tumor antigen p53 (TP53) ELISA Kit |
SKU: | HUEB0349 |
Size: | 96T |
Target: | Human Cellular tumor antigen p53 (TP53) |
Synonyms: | Antigen NY-CO-13, Phosphoprotein p53, Tumor suppressor p53, P53 |
Assay Type: | Sandwich |
Detection Method: | ELISA |
Reactivity: | Human |
Detection Range: | 0.156-10ng/ml |
Sensitivity: | 0.089ng/mL |
Intra CV: | 5.7% | ||||||||||||||||||||
Inter CV: | 8.3% | ||||||||||||||||||||
Linearity: |
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Recovery: |
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Function: | Acts as a tumor suppressor in many tumor types; induces growth arrest or apoptosis depending on the physiological circumstances and cell type. Involved in cell cycle regulation as a trans-activator that acts to negatively regulate cell division by controlling a set of genes required for this process. One of the activated genes is an inhibitor of cyclin-dependent kinases. Apoptosis induction seems to be mediated either by stimulation of BAX and FAS antigen expression, or by repression of Bcl-2 expression. In cooperation with mitochondrial PPIF is involved in activating oxidative stress-induced necrosis; the function is largely independent of transcription. Induces the transcription of long intergenic non-coding RNA p21 (lincRNA-p21) and lincRNA-Mkln1. LincRNA-p21 participates in TP53-dependent transcriptional repression leading to apoptosis and seem to have to effect on cell-cycle regulation. Implicated in Notch signaling cross-over. Prevents CDK7 kinase activity when associated to CAK complex in response to DNA damage, thus stopping cell cycle progression. Isoform 2 enhances the transactivation activity of isoform 1 from some but not all TP53-inducible promoters. Isoform 4 suppresses transactivation activity and impairs growth suppression mediated by isoform 1. Isoform 7 inhibits isoform 1-mediated apoptosis. Regulates the circadian clock by repressing CLOCK-ARNTL/BMAL1-mediated transcriptional activation of PER2 (PubMed:24051492). |
Uniprot: | P04637 |
Sample Type: | Serum, plasma, tissue homogenates, cell culture supernates and other biological fluids |
Specificity: | Natural and recombinant human Cellular tumor antigen p53 |
Sub Unit: | Interacts with AXIN1. Probably part of a complex consisting of TP53, HIPK2 and AXIN1 (By similarity). Binds DNA as a homotetramer. Interacts with histone acetyltransferases EP300 and methyltransferases HRMT1L2 and CARM1, and recruits them to promoters. In vitro, the interaction of TP53 with cancer-associated/HPV (E6) viral proteins leads to ubiquitination and degradation of TP53 giving a possible model for cell growth regulation. This complex formation requires an additional factor, E6-AP, which stably associates with TP53 in the presence of E6. Interacts (via C-terminus) with TAF1; when TAF1 is part of the TFIID complex. Interacts with ING4; this interaction may be indirect. Found in a complex with CABLES1 and TP73. Interacts with HIPK1, HIPK2, and TP53INP1. Interacts with WWOX. May interact with HCV core protein. Interacts with USP7 and SYVN1. Interacts with HSP90AB1. Interacts with CHD8; leading to recruit histone H1 and prevent transactivation activity (By similarity). Interacts with ARMC10, BANP, CDKN2AIP, NUAK1, STK11/LKB1, UHRF2 and E4F1. Interacts with YWHAZ; the interaction enhances TP53 transcriptional activity. Phosphorylation of YWHAZ on 'Ser-58' inhibits this interaction. Interacts (via DNA-binding domain) with MAML1 (via N-terminus). Interacts with MKRN1. Interacts with PML (via C-terminus). Interacts with MDM2; leading to ubiquitination and proteasomal degradation of TP53. Directly interacts with FBXO42; leading to ubiquitination and degradation of TP53. Interacts (phosphorylated at Ser-15 by ATM) with the phosphatase PP2A-PPP2R5C holoenzyme; regulates stress-induced TP53-dependent inhibition of cell proliferation. Interacts with PPP2R2A. Interacts with AURKA, DAXX, BRD7 and TRIM24. Interacts (when monomethylated at Lys-382) with L3MBTL1. Isoform 1 interacts with isoform 2 and with isoform 4. Interacts with GRK5. Binds to the CAK complex (CDK7, cyclin H and MAT1) in response to DNA damage. Interacts with CDK5 in neurons. Interacts with AURKB, SETD2, UHRF2 and NOC2L. Interacts (via N-terminus) with PTK2/FAK1; this promotes ubiquitination by MDM2. Interacts with PTK2B/PYK2; this promotes ubiquitination by MDM2. Interacts with PRKCG. Interacts with PPIF; the association implicates preferentially tetrameric TP53, is induced by oxidative stress and is impaired by cyclosporin A (CsA). Interacts with human cytomegalovirus/HHV-5 protein UL123. Interacts with SNAI1; the interaction induces SNAI1 degradation via MDM2-mediated ubiquitination and inhibits SNAI1-induced cell invasion. Interacts with KAT6A. Interacts with UBC9. Interacts with ZNF385B; the interaction is direct. Interacts (via DNA-binding domain) with ZNF385A; the interaction is direct and enhances p53/TP53 transactivation functions on cell-cycle arrest target genes, resulting in growth arrest. Interacts with ANKRD2. Interacts with RFFL and RNF34; involved in p53/TP53 ubiquitination. Interacts with MTA1 and RFWD2. Interacts with CCAR2 (via N-terminus). Interacts (via N-terminus) with human adenovirus 5 E1B-55K protein; this interaction leads to the inhibition of TP53 function and/or its degradation (PubMed:25772236). Interacts with MORC3 (PubMed:17332504). Interacts (via C-terminus) with POU4F2 isoform 1 (via C-terminus) (PubMed:17145718). |
Research Area: | Neurosciences |
Subcellular Location: | Isoform 9 Cytoplasm |
Storage: | Please see kit components below for exact storage details |
Note: | For research use only |
UniProt Protein Function: | Function: Acts as a tumor suppressor in many tumor types; induces growth arrest or apoptosis depending on the physiological circumstances and cell type. Involved in cell cycle regulation as a trans-activator that acts to negatively regulate cell division by controlling a set of genes required for this process. One of the activated genes is an inhibitor of cyclin-dependent kinases. Apoptosis induction seems to be mediated either by stimulation of BAX and FAS antigen expression, or by repression of Bcl-2 expression. In cooperation with mitochondrial PPIF is involved in activating oxidative stress-induced necrosis; the function is largely independent of transcription. Induces the transcription of long intergenic non-coding RNA p21 (lincRNA-p21) and lincRNA-Mkln1. LincRNA-p21 participates in TP53-dependent transcriptional repression leading to apoptosis and seem to have to effect on cell-cycle regulation. Implicated in Notch signaling cross-over. Prevents CDK7 kinase activity when associated to CAK complex in response to DNA damage, thus stopping cell cycle progression. Isoform 2 enhances the transactivation activity of isoform 1 from some but not all TP53-inducible promoters. Isoform 4 suppresses transactivation activity and impairs growth suppression mediated by isoform 1. Isoform 7 inhibits isoform 1-mediatedapoptosis. Ref.34 Ref.42 Ref.61 Ref.66 Ref.70 Ref.92 Ref.94 Ref.106 Ref.109 Ref.121 Ref.124 |
UniProt Protein Details: | Cofactor: Binds 1 zinc ion per subunit. Subunit structure: Interacts with AXIN1. Probably part of a complex consisting of TP53, HIPK2 and AXIN1 By similarity. Binds DNA as a homotetramer. Interacts with histone acetyltransferases EP300 and methyltransferases HRMT1L2 and CARM1, and recruits them to promoters. In vitro, the interaction of TP53 with cancer-associated/HPV (E6) viral proteins leads to ubiquitination and degradation of TP53 giving a possible model for cell growth regulation. This complex formation requires an additional factor, E6-AP, which stably associates with TP53 in the presence of E6. Interacts (via C-terminus) with TAF1; when TAF1 is part of the TFIID complex. Interacts with ING4; this interaction may be indirect. Found in a complex with CABLES1 and TP73. Interacts with HIPK1, HIPK2, and TP53INP1. Interacts with WWOX. May interact with HCV core protein. Interacts with USP7 and SYVN1. Interacts with HSP90AB1. Interacts with CHD8; leading to recruit histone H1 and prevent transactivation activity By similarity. Interacts with ARMC10, BANP, CDKN2AIP, NUAK1, STK11/LKB1, UHRF2 and E4F1. Interacts with YWHAZ; the interaction enhances TP53 transcriptional activity. Phosphorylation of YWHAZ on 'Ser-58' inhibits this interaction. Interacts (via DNA-binding domain) with MAML1 (via N-terminus). Interacts with MKRN1. Interacts with PML (via C-terminus). Interacts with MDM2; leading to ubiquitination and proteasomal degradation of TP53. Directly interacts with FBXO42; leading to ubiquitination and degradation of TP53. Interacts (phosphorylated at Ser-15 by ATM) with the phosphatase PP2A-PPP2R5C holoenzyme; regulates stress-induced TP53-dependent inhibition of cell proliferation. Interacts with PPP2R2A. Interacts with AURKA, DAXX, BRD7 and TRIM24. Interacts (when monomethylated at Lys-382) with L3MBTL1. Isoform 1 interacts with isoform 2 and with isoform 4. Interacts with GRK5. Binds to the CAK complex (CDK7, cyclin H and MAT1) in response to DNA damage. Interacts with CDK5 in neurons. Interacts with AURKB, SETD2, UHRF2 and NOC2L. Interacts (via N-terminus) with PTK2/FAK1; this promotes ubiquitination by MDM2. Interacts with PTK2B/PYK2; this promotes ubiquitination by MDM2. Interacts with PRKCG. Interacts with PPIF; the association implicates preferentially tetrameric TP53, is induced by oxidative stress and is impaired by cyclosporin A (CsA). Interacts with human cytomegalovirus/HHV-5 protein UL123. Interacts with SNAI1; the interaction induces SNAI1 degradation via MDM2-mediated ubiquitination and inhibits SNAI1-induced cell invasion. Interacts with KAT6A. Interacts with UBC9. Interacts with ZNF385B; the interaction is direct. Interacts (via DNA-binding domain) with ZNF385A; the interaction is direct and enhances p53/TP53 transactivation functions on cell-cycle arrest target genes, resulting in growth arrest. Interacts with ANKRD2. Ref.8 Ref.34 Ref.38 Ref.42 Ref.43 Ref.54 Ref.55 Ref.56 Ref.57 Ref.58 Ref.59 Ref.61 Ref.62 Ref.64 Ref.65 Ref.66 Ref.67 Ref.68 Ref.72 Ref.73 Ref.74 Ref.75 Ref.76 Ref.78 Ref.80 Ref.81 Ref.83 Ref.86 Ref.87 Ref.88 Ref.89 Ref.92 Ref.93 Ref.98 Ref.100 Ref.102 Ref.104 Ref.105 Ref.106 Ref.111 Ref.112 Ref.115 Ref.116 Ref.118 Ref.120 Ref.121 Ref.123 Ref.124 Ref.125 Ref.126 Ref.128 Ref.136 Ref.137 Ref.138 Ref.139 Ref.140 Ref.150 Subcellular location: Cytoplasm Ref.9 Ref.38 Ref.42 Ref.51 Ref.61 Ref.70 Ref.74 Ref.87 Ref.93 Ref.99 Ref.112 Ref.124. Nucleus. Nucleus › PML body. Endoplasmic reticulum. Mitochondrion matrix. Note: Interaction with BANP promotes nuclear localization. Recruited into PML bodies together with CHEK2. Translocates to mitochondria upon oxidative stress. Ref.9 Ref.38 Ref.42 Ref.51 Ref.61 Ref.70 Ref.74 Ref.87 Ref.93 Ref.99 Ref.112 Ref.124Isoform 1: Nucleus. Cytoplasm Ref.9 Ref.38 Ref.42 Ref.51 Ref.61 Ref.70 Ref.74 Ref.87 Ref.93 Ref.99 Ref.112 Ref.124. Note: Predominantly nuclear but localizes to the cytoplasm when expressed with isoform 4. Ref.9 Ref.38 Ref.42 Ref.51 Ref.61 Ref.70 Ref.74 Ref.87 Ref.93 Ref.99 Ref.112 Ref.124Isoform 2: Nucleus. Cytoplasm Ref.9 Ref.38 Ref.42 Ref.51 Ref.61 Ref.70 Ref.74 Ref.87 Ref.93 Ref.99 Ref.112 Ref.124. Note: Localized mainly in the nucleus with minor staining in the cytoplasm. Ref.9 Ref.38 Ref.42 Ref.51 Ref.61 Ref.70 Ref.74 Ref.87 Ref.93 Ref.99 Ref.112 Ref.124Isoform 3: Nucleus. Cytoplasm Ref.9 Ref.38 Ref.42 Ref.51 Ref.61 Ref.70 Ref.74 Ref.87 Ref.93 Ref.99 Ref.112 Ref.124. Note: Localized in the nucleus in most cells but found in the cytoplasm in some cells. Ref.9 Ref.38 Ref.42 Ref.51 Ref.61 Ref.70 Ref.74 Ref.87 Ref.93 Ref.99 Ref.112 Ref.124Isoform 4: Nucleus. Cytoplasm Ref.9 Ref.38 Ref.42 Ref.51 Ref.61 Ref.70 Ref.74 Ref.87 Ref.93 Ref.99 Ref.112 Ref.124. Note: Predominantly nuclear but translocates to the cytoplasm following cell stress. Ref.9 Ref.38 Ref.42 Ref.51 Ref.61 Ref.70 Ref.74 Ref.87 Ref.93 Ref.99 Ref.112 Ref.124Isoform 7: Nucleus. Cytoplasm Ref.9 Ref.38 Ref.42 Ref.51 Ref.61 Ref.70 Ref.74 Ref.87 Ref.93 Ref.99 Ref.112 Ref.124. Note: Localized mainly in the nucleus with minor staining in the cytoplasm. Ref.9 Ref.38 Ref.42 Ref.51 Ref.61 Ref.70 Ref.74 Ref.87 Ref.93 Ref.99 Ref.112 Ref.124Isoform 8: Nucleus. Cytoplasm Ref.9 Ref.38 Ref.42 Ref.51 Ref.61 Ref.70 Ref.74 Ref.87 Ref.93 Ref.99 Ref.112 Ref.124. Note: Localized in both nucleus and cytoplasm in most cells. In some cells, forms foci in the nucleus that are different from nucleoli. Ref.9 Ref.38 Ref.42 Ref.51 Ref.61 Ref.70 Ref.74 Ref.87 Ref.93 Ref.99 Ref.112 Ref.124Isoform 9: Cytoplasm Ref.9 Ref.38 Ref.42 Ref.51 Ref.61 Ref.70 Ref.74 Ref.87 Ref.93 Ref.99 Ref.112 Ref.124. Tissue specificity: Ubiquitous. Isoforms are expressed in a wide range of normal tissues but in a tissue-dependent manner. Isoform 2 is expressed in most normal tissues but is not detected in brain, lung, prostate, muscle, fetal brain, spinal cord and fetal liver. Isoform 3 is expressed in most normal tissues but is not detected in lung, spleen, testis, fetal brain, spinal cord and fetal liver. Isoform 7 is expressed in most normal tissues but is not detected in prostate, uterus, skeletal muscle and breast. Isoform 8 is detected only in colon, bone marrow, testis, fetal brain and intestine. Isoform 9 is expressed in most normal tissues but is not detected in brain, heart, lung, fetal liver, salivary gland, breast or intestine. Ref.9 Induction: Up-regulated in response to DNA damage. Isoform 2 is not induced in tumor cells in response to stress. Ref.9 Ref.38 Domain: The nuclear export signal acts as a transcriptional repression domain. The TADI and TADII motifs (residues 17 to 25 and 48 to 56) correspond both to 9aaTAD motifs which are transactivation domains present in a large number of yeast and animal transcription factors. Ref.48 Ref.91 Post-translational modification: Acetylated. Acetylation of Lys-382 by CREBBP enhances transcriptional activity. Deacetylation of Lys-382 by SIRT1 impairs its ability to induce proapoptotic program and modulate cell senescence. Ref.40 Ref.47 Ref.60 Ref.116 Ref.128Phosphorylation on Ser residues mediates transcriptional activation. Phosphorylated by HIPK1 By similarity. Phosphorylation at Ser-9 by HIPK4 increases repression activity on BIRC5 promoter. Phosphorylated on Thr-18 by VRK1. Phosphorylated on Ser-20 by CHEK2 in response to DNA damage, which prevents ubiquitination by MDM2. Phosphorylated on Ser-20 by PLK3 in response to reactive oxygen species (ROS), promoting p53/TP53-mediated apoptosis. Phosphorylated on Thr-55 by TAF1, which promotes MDM2-mediated degradation. Phosphorylated on Ser-33 by CDK7 in a CAK complex in response to DNA damage. Phosphorylated on Ser-46 by HIPK2 upon UV irradiation. Phosphorylation on Ser-46 is required for acetylation by CREBBP. Phosphorylated on Ser-392 following UV but not gamma irradiation. Phosphorylated on Ser-15 upon ultraviolet irradiation; which is enhanced by interaction with BANP. Phosphorylated by NUAK1 at Ser-15 and Ser-392; was intially thought to be mediated by STK11/LKB1 but it was later shown that it is indirect and that STK11/LKB1-dependent phosphorylation is probably mediated by downstream NUAK1 (Ref.123). It is unclear whether AMP directly mediates phosphorylation at Ser-15. Phosphorylated on Thr-18 by isoform 1 and isoform 2 of VRK2. Phosphorylation on Thr-18 by isoform 2 of VRK2 results in a reduction in ubiquitination by MDM2 and an increase in acetylation by EP300. Stabilized by CDK5-mediated phosphorylation in response to genotoxic and oxidative stresses at Ser-15, Ser-33 and Ser-46, leading to accumulation of p53/TP53, particularly in the nucleus, thus inducing the transactivation of p53/TP53 target genes. Phosphorylated by DYRK2 at Ser-46 in response to genotoxic stress. Phosphorylated at Ser-315 and Ser-392 by CDK2 in response to DNA-damage. Ref.28 Ref.29 Ref.30 Ref.33 Ref.36 Ref.38 Ref.41 Ref.44 Ref.46 Ref.49 Ref.50 Ref.52 Ref.53 Ref.57 Ref.58 Ref.61 Ref.68 Ref.72 Ref.74 Ref.77 Ref.78 Ref.79 Ref.81 Ref.85 Ref.90 Ref.93 Ref.94 Ref.100 Ref.110 Ref.115 Ref.121 Ref.123 Ref.125Dephosphorylated by PP2A-PPP2R5C holoenzyme at Thr-55. SV40 small T antigen inhibits the dephosphorylation by the AC form of PP2A. Ref.28 Ref.29 Ref.30 Ref.33 Ref.36 Ref.38 Ref.41 Ref.44 Ref.46 Ref.49 Ref.50 Ref.52 Ref.53 Ref.57 Ref.58 Ref.61 Ref.68 Ref.72 Ref.74 Ref.77 Ref.78 Ref.79 Ref.81 Ref.85 Ref.90 Ref.93 Ref.94 Ref.100 Ref.110 Ref.115 Ref.121 Ref.123 Ref.125May be O-glycosylated in the C-terminal basic region. Studied in EB-1 cell line. Ref.32Ubiquitinated by MDM2 and SYVN1, which leads to proteasomal degradation. Ubiquitinated by RFWD3, which works in cooperation with MDM2 and may catalyze the formation of short polyubiquitin chains on p53/TP53 that are not targeted to the proteasome. Ubiquitinated by MKRN1 at Lys-291 and Lys-292, which leads to proteasomal degradation. Deubiquitinated by USP10, leading to its stabilization. Ubiquitinated by TRIM24, which leads to proteasomal degradation. Ubiquitination by TOPORS induces degradation. Deubiquitination by USP7, leading to stabilization. Isoform 4 is monoubiquitinated in an MDM2-independent manner. Ref.39 Ref.61 Ref.69 Ref.70 Ref.87 Ref.99 Ref.102 Ref.103 Ref.106 Ref.108 Ref.112 Ref.117Monomethylated at Lys-372 by SETD7, leading to stabilization and increased transcriptional activation. Monomethylated at Lys-370 by SMYD2, leading to decreased DNA-binding activity and subsequent transcriptional regulation activity. Lys-372 monomethylation prevents interaction with SMYD2 and subsequent monomethylation at Lys-370. Dimethylated at Lys-373 by EHMT1 and EHMT2. Monomethylated at Lys-382 by SETD8, promoting interaction with L3MBTL1 and leading to repress transcriptional activity. Dimethylation at Lys-370 and Lys-382 diminishes p53 ubiquitination, through stabilizing association with the methyl reader PHF20. Demethylation of dimethylated Lys-370 by KDM1A prevents interaction with TP53BP1 and represses TP53-mediated transcriptional activation. Ref.71 Ref.82 Ref.84 Ref.95 Ref.96 Ref.113 Ref.127 Ref.140Sumoylated with SUMO1. Sumoylated at Lys-386 by UBC9. Ref.35 Ref.51 Ref.125 Involvement in disease: TP53 is found in increased amounts in a wide variety of transformed cells. TP53 is frequently mutated or inactivated in about 60% of cancers. TP53 defects are found in Barrett metaplasia a condition in which the normally stratified squamous epithelium of the lower esophagus is replaced by a metaplastic columnar epithelium. The condition develops as a complication in approximately 10% of patients with chronic gastroesophageal reflux disease and predisposes to the development of esophageal adenocarcinoma.Esophageal cancer (ESCR) [MIM:133239]: A malignancy of the esophagus. The most common types are esophageal squamous cell carcinoma and adenocarcinoma. Cancer of the esophagus remains a devastating disease because it is usually not detected until it has progressed to an advanced incurable stage.Note: The disease is caused by mutations affecting the gene represented in this entry.Li-Fraumeni syndrome (LFS) [MIM:151623]: Autosomal dominant familial cancer syndrome that in its classic form is defined by the existence of a proband affected by a sarcoma before 45 years with a first degree relative affected by any tumor before 45 years and another first degree relative with any tumor before 45 years or a sarcoma at any age. Other clinical definitions for LFS have been proposed (PubMed:8118819 and PubMed:8718514) and called Li-Fraumeni like syndrome (LFL). In these families affected relatives develop a diverse set of malignancies at unusually early ages. Four types of cancers account for 80% of tumors occurring in TP53 germline mutation carriers: breast cancers, soft tissue and bone sarcomas, brain tumors (astrocytomas) and adrenocortical carcinomas. Less frequent tumors include choroid plexus carcinoma or papilloma before the age of 15, rhabdomyosarcoma before the age of 5, leukemia, Wilms tumor, malignant phyllodes tumor, colorectal and gastric cancers.Note: The disease is caused by mutations affecting the gene represented in this entry. Ref.38 Ref.152 Ref.153 Ref.154 Ref.155 Ref.156 Ref.175 Ref.177 Ref.182 Ref.183Squamous cell carcinoma of the head and neck (HNSCC) [MIM:275355]: A non-melanoma skin cancer affecting the head and neck. The hallmark of cutaneous SCC is malignant transformation of normal epidermal keratinocytes.Note: The gene represented in this entry is involved in disease pathogenesis.Lung cancer (LNCR) [MIM:211980]: A common malignancy affecting tissues of the lung. The most common form of lung cancer is non-small cell lung cancer (NSCLC) that can be divided into 3 major histologic subtypes: squamous cell carcinoma, adenocarcinoma, and large cell lung cancer. NSCLC is often diagnosed at an advanced stage and has a poor prognosis.Note: The disease is caused by mutations affecting the gene represented in this entry.Choroid plexus papilloma (CPLPA) [MIM:260500]: Slow-growing benign tumor of the choroid plexus that often invades the leptomeninges. In children it is usually in a lateral ventricle but in adults it is more often in the fourth ventricle. Hydrocephalus is common, either from obstruction or from tumor secretion of cerebrospinal fluid. If it undergoes malignant transformation it is called a choroid plexus carcinoma. Primary choroid plexus tumors are rare and usually occur in early childhood.Note: The disease is caused by mutations affecting the gene represented in this entry. Ref.186Adrenocortical carcinoma (ADCC) [MIM:202300]: A malignant neoplasm of the adrenal cortex and a rare childhood tumor. It occurs with increased frequency in patients with Beckwith-Wiedemann syndrome and Li-Fraumeni syndrome.Note: The disease is caused by mutations affecting the gene represented in this entry. Ref.185Basal cell carcinoma 7 (BCC7) [MIM:614740]: A common malignant skin neoplasm that typically appears on hair-bearing skin, most commonly on sun-exposed areas. It is slow growing and rarely metastasizes, but has potentialities for local invasion and destruction. It usually develops as a flat, firm, pale area that is small, raised, pink or red, translucent, shiny, and waxy, and the area may bleed following minor injury. Tumor size can vary from a few millimeters to several centimeters in diameter.Note: Disease susceptibility is associated with variations affecting the gene represented in this entry. Ref.122 Sequence similarities: Belongs to the p53 family. |
NCBI Summary: | This gene encodes a tumor suppressor protein containing transcriptional activation, DNA binding, and oligomerization domains. The encoded protein responds to diverse cellular stresses to regulate expression of target genes, thereby inducing cell cycle arrest, apoptosis, senescence, DNA repair, or changes in metabolism. Mutations in this gene are associated with a variety of human cancers, including hereditary cancers such as Li-Fraumeni syndrome. Alternative splicing of this gene and the use of alternate promoters result in multiple transcript variants and isoforms. Additional isoforms have also been shown to result from the use of alternate translation initiation codons (PMIDs: 12032546, 20937277). [provided by RefSeq, Feb 2013] |
UniProt Code: | P04637 |
NCBI GenInfo Identifier: | 269849759 |
NCBI Gene ID: | 7157 |
NCBI Accession: | P04637.4 |
UniProt Secondary Accession: | P04637,Q15086, Q15087, Q15088, Q16535, Q16807, Q16808 Q16809, Q16810, Q16811, Q16848, Q2XN98, |
UniProt Related Accession: | P04637 |
Molecular Weight: | 43,653 Da |
NCBI Full Name: | Cellular tumor antigen p53 |
NCBI Synonym Full Names: | tumor protein p53 |
NCBI Official Symbol: | TP53 |
NCBI Official Synonym Symbols: | P53; BCC7; LFS1; TRP53 |
NCBI Protein Information: | cellular tumor antigen p53; antigen NY-CO-13; tumor protein 53; phosphoprotein p53; p53 tumor suppressor; mutant tumor protein 53; transformation-related protein 53 |
UniProt Protein Name: | Cellular tumor antigen p53 |
UniProt Synonym Protein Names: | Antigen NY-CO-13; Phosphoprotein p53; Tumor suppressor p53 |
Protein Family: | p53 and DNA damage-regulated protein |
UniProt Gene Name: | TP53 |
UniProt Entry Name: | P53_HUMAN |
Component | Quantity (96 Assays) | Storage |
ELISA Microplate (Dismountable) | 8×12 strips | -20°C |
Lyophilized Standard | 2 | -20°C |
Sample Diluent | 20ml | -20°C |
Assay Diluent A | 10mL | -20°C |
Assay Diluent B | 10mL | -20°C |
Detection Reagent A | 120µL | -20°C |
Detection Reagent B | 120µL | -20°C |
Wash Buffer | 30mL | 4°C |
Substrate | 10mL | 4°C |
Stop Solution | 10mL | 4°C |
Plate Sealer | 5 | - |
Other materials and equipment required:
- Microplate reader with 450 nm wavelength filter
- Multichannel Pipette, Pipette, microcentrifuge tubes and disposable pipette tips
- Incubator
- Deionized or distilled water
- Absorbent paper
- Buffer resevoir
*Note: The below protocol is a sample protocol. Protocols are specific to each batch/lot. For the correct instructions please follow the protocol included in your kit.
Allow all reagents to reach room temperature (Please do not dissolve the reagents at 37°C directly). All the reagents should be mixed thoroughly by gently swirling before pipetting. Avoid foaming. Keep appropriate numbers of strips for 1 experiment and remove extra strips from microtiter plate. Removed strips should be resealed and stored at -20°C until the kits expiry date. Prepare all reagents, working standards and samples as directed in the previous sections. Please predict the concentration before assaying. If values for these are not within the range of the standard curve, users must determine the optimal sample dilutions for their experiments. We recommend running all samples in duplicate.
Step | |
1. | Add Sample: Add 100µL of Standard, Blank, or Sample per well. The blank well is added with Sample diluent. Solutions are added to the bottom of micro ELISA plate well, avoid inside wall touching and foaming as possible. Mix it gently. Cover the plate with sealer we provided. Incubate for 120 minutes at 37°C. |
2. | Remove the liquid from each well, don't wash. Add 100µL of Detection Reagent A working solution to each well. Cover with the Plate sealer. Gently tap the plate to ensure thorough mixing. Incubate for 1 hour at 37°C. Note: if Detection Reagent A appears cloudy warm to room temperature until solution is uniform. |
3. | Aspirate each well and wash, repeating the process three times. Wash by filling each well with Wash Buffer (approximately 400µL) (a squirt bottle, multi-channel pipette,manifold dispenser or automated washer are needed). Complete removal of liquid at each step is essential. After the last wash, completely remove remaining Wash Buffer by aspirating or decanting. Invert the plate and pat it against thick clean absorbent paper. |
4. | Add 100µL of Detection Reagent B working solution to each well. Cover with the Plate sealer. Incubate for 60 minutes at 37°C. |
5. | Repeat the wash process for five times as conducted in step 3. |
6. | Add 90µL of Substrate Solution to each well. Cover with a new Plate sealer and incubate for 10-20 minutes at 37°C. Protect the plate from light. The reaction time can be shortened or extended according to the actual color change, but this should not exceed more than 30 minutes. When apparent gradient appears in standard wells, user should terminatethe reaction. |
7. | Add 50µL of Stop Solution to each well. If color change does not appear uniform, gently tap the plate to ensure thorough mixing. |
8. | Determine the optical density (OD value) of each well at once, using a micro-plate reader set to 450 nm. User should open the micro-plate reader in advance, preheat the instrument, and set the testing parameters. |
9. | After experiment, store all reagents according to the specified storage temperature respectively until their expiry. |
When carrying out an ELISA assay it is important to prepare your samples in order to achieve the best possible results. Below we have a list of procedures for the preparation of samples for different sample types.
Sample Type | Protocol |
Serum | If using serum separator tubes, allow samples to clot for 30 minutes at room temperature. Centrifuge for 10 minutes at 1,000x g. Collect the serum fraction and assay promptly or aliquot and store the samples at -80°C. Avoid multiple freeze-thaw cycles. If serum separator tubes are not being used, allow samples to clot overnight at 2-8°C. Centrifuge for 10 minutes at 1,000x g. Remove serum and assay promptly or aliquot and store the samples at -80°C. Avoid multiple freeze-thaw cycles. |
Plasma | Collect plasma using EDTA or heparin as an anticoagulant. Centrifuge samples at 4°C for 15 mins at 1000 × g within 30 mins of collection. Collect the plasma fraction and assay promptly or aliquot and store the samples at -80°C. Avoid multiple freeze-thaw cycles. Note: Over haemolysed samples are not suitable for use with this kit. |
Urine & Cerebrospinal Fluid | Collect the urine (mid-stream) in a sterile container, centrifuge for 20 mins at 2000-3000 rpm. Remove supernatant and assay immediately. If any precipitation is detected, repeat the centrifugation step. A similar protocol can be used for cerebrospinal fluid. |
Cell culture supernatant | Collect the cell culture media by pipette, followed by centrifugation at 4°C for 20 mins at 1500 rpm. Collect the clear supernatant and assay immediately. |
Cell lysates | Solubilize cells in lysis buffer and allow to sit on ice for 30 minutes. Centrifuge tubes at 14,000 x g for 5 minutes to remove insoluble material. Aliquot the supernatant into a new tube and discard the remaining whole cell extract. Quantify total protein concentration using a total protein assay. Assay immediately or aliquot and store at ≤ -20 °C. |
Tissue homogenates | The preparation of tissue homogenates will vary depending upon tissue type. Rinse tissue with 1X PBS to remove excess blood & homogenize in 20ml of 1X PBS (including protease inhibitors) and store overnight at ≤ -20°C. Two freeze-thaw cycles are required to break the cell membranes. To further disrupt the cell membranes you can sonicate the samples. Centrifuge homogenates for 5 mins at 5000xg. Remove the supernatant and assay immediately or aliquot and store at -20°C or -80°C. |
Tissue lysates | Rinse tissue with PBS, cut into 1-2 mm pieces, and homogenize with a tissue homogenizer in PBS. Add an equal volume of RIPA buffer containing protease inhibitors and lyse tissues at room temperature for 30 minutes with gentle agitation. Centrifuge to remove debris. Quantify total protein concentration using a total protein assay. Assay immediately or aliquot and store at ≤ -20 °C. |
Breast Milk | Collect milk samples and centrifuge at 10,000 x g for 60 min at 4°C. Aliquot the supernatant and assay. For long term use, store samples at -80°C. Minimize freeze/thaw cycles. |