| Field | Specification |
|---|---|
| Mfr No | |
| Alternative Names | Aspartate aminotransferase, cytoplasmic|cAspAT|Cysteine aminotransferase, cytoplasmic|Cysteine transaminase, cytoplasmic|cCAT|Glutamate oxaloacetate transaminase 1|Transaminase A|GOT1 |
| Assay Time | |
| Detection Method | |
| Detection Range | |
| Product Type | |
| Reactivity | |
| Sample Type(s) | Serum, Plasma, Cell Culture Supernatant, cell or tissue lysate, Other liquid samples |
| Sensitivity | |
| Species | |
| Storage | |
| Target |
Background
mouse AST (Aspartate Aminotransferase) is a molecular target commonly studied in biomedical research. Enzymes contribute to cellular physiology through catalytic activity that supports metabolism, nucleic-acid processing, or signaling.
Biological role and mechanism
The biological role of AST is typically understood in terms of its molecular category and interaction network. Depending on the model system, it may participate in cell–cell communication, intracellular signaling, enzymatic processing, or regulation of gene expression programs. Mechanistic interpretation is often strengthened by considering upstream regulators and downstream readouts rather than relying on a single marker.
Expression and abundance of AST can vary by tissue, cell type, and physiological state. In many systems, levels are influenced by factors such as developmental stage, immune activation, metabolic status, and cellular stress. Because sample matrix and pre-analytical handling can affect measured concentrations, interpretation is typically strongest when experiments keep collection and processing consistent across groups.
Nomenclature and related terms
AST (Aspartate Aminotransferase) may also be referenced as Aspartate aminotransferase, cytoplasmic, cAspAT, and Cysteine aminotransferase, cytoplasmic in the literature or in databases. When comparing results across studies, confirm that the reported analyte refers to the same molecule, species context, and molecular form (e.g., precursor vs mature protein, or soluble vs membrane-associated forms).
Why it matters in research
- Understanding how AST relates to signal transduction, tissue homeostasis, stress responses, and disease-model biology in biomedical research.
- Interpreting shifts in AST levels alongside other pathway components or complementary markers.
- Connecting molecular changes to phenotypes such as inflammation, remodeling, metabolism shifts, or cell-state transitions (context-dependent).
Molecular forms and interpretation
For some targets, isoforms, proteolytic processing, or post-translational modifications (such as phosphorylation or glycosylation) can influence function and apparent abundance. If multiple molecular forms are expected in your model, align interpretation with the form most relevant to the biological question.
Disease and translational relevance
AST has been investigated across diverse physiological and disease contexts, and changes in its abundance have been reported in areas aligned with biomedical studies. These associations are interpreted as research findings rather than diagnostic or therapeutic claims, and they should be evaluated alongside model-specific covariates and study design.
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