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research use only
UTF-1 Antibody [B24H16]
Cat.No.: F4388
Application:
Reactivity:
Usage Information
| Dilution |
|---|
|
|
| Application |
|---|
| WB, ICC, ELISA |
| Reactivity |
|---|
| Mouse, Human |
| Source |
|---|
| Mouse Monoclonal Antibody |
| Storage Buffer |
|---|
| PBS, pH 7.2+50% Glycerol+0.05% BSA+0.01% NaN3 |
| Storage (from the date of receipt) |
|---|
| -20°C (avoid freeze-thaw cycles), 2 years |
| Predicted MW |
|---|
| 36 kDa |
Biological Description
| Specificity |
|---|
| UTF-1 Antibody [B24H16] detects endogenous levels of total UTF-1 protein. |
| Clone |
|---|
| B24H16 |
| Synonym(s) |
|---|
| Undifferentiated embryonic cell transcription factor 1, UTF1 |
| Background |
|---|
| UTF‑1 (undifferentiated embryonic cell transcription factor 1) is a proline‑rich, chromatin‑associated transcriptional cofactor that localizes to the nucleus of pluripotent embryonic stem and carcinoma cells and of early embryonic lineages, where it integrates with core pluripotency networks to control transcriptional output and differentiation competence. The protein contains a leucine‑zipper–like region and acidic and basic low‑complexity segments that support interaction with transcription factors and basal transcription machinery, and it associates tightly with chromatin in a manner that resembles core histone interaction, positioning UTF‑1 as a structural and functional chromatin component in pluripotent cells. UTF‑1 expression is prominent in inner cell mass, primitive ectoderm, extra‑embryonic tissues, embryonic stem and carcinoma cells, and early germ cells, and declines rapidly upon somatic differentiation while remaining detectable in germline compartments and adult gonads, linking UTF‑1 presence to pluripotent or germline‑related transcriptional states. UTF‑1 functions as a transcriptional coactivator by binding the activation domain of ATF2 and engaging the TFIID complex, thereby enhancing transcription from ATF‑dependent promoters and connecting sequence‑specific transcription factors with the basal transcription apparatus, and it also shows transcriptional repressor activity in embryonic stem cells, where it contributes to controlled expression of pluripotency‑associated genes. UTF‑1 helps establish and maintain a chromatin environment that supports pluripotency while limiting transcriptional noise, buffering mRNA levels through promotion of mRNA degradation at selected loci, and enabling proper initiation of lineage‑specific transcriptional programs during exit from the pluripotent state. Perturbation of UTF‑1 levels interferes with normal differentiation capacity of embryonic stem and carcinoma cells while leaving basic self‑renewal properties largely intact, indicating a role as a gatekeeper that couples chromatin organization and transcriptional cofactor activity to controlled progression from pluripotent to committed states. UTF‑1 expression extends beyond classical stem cell compartments into certain adult epithelia and germ cell neoplasms, and in human cancer contexts UTF‑1 shows tissue‑dependent behavior with characteristics of either an oncogenic factor or a tumor suppressor, emphasizing that UTF‑1‑dependent chromatin and transcriptional control can influence tumor cell differentiation status and growth potential in a context‑specific fashion. |
| References |
|---|
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