Basal and stress-inducible expression of HSPA6 in human keratinocytes is regulated by negative and positive promoter regions
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- 作者:Vincent P. Ramirez (1)
Michael Stamatis (2)
Anastasia Shmukler (2)
Brian J. Aneskievich (3) (4) - 关键词:HSP70B-promoter ; HSE ; AP1 ; HSF ; Keratinocyte
- 刊名:Cell Stress and Chaperones
- 出版年:2015
- 出版时间:January 2015
- 年:2015
- 卷:20
- 期:1
- 页码:95-107
- 全文大小:1,710 KB
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文摘
Epidermal keratinocytes serve as the primary barrier between the body and environmental stressors. They are subjected to numerous stress events and are likely to respond with a repertoire of heat shock proteins (HSPs). HSPA6 (HSP70B- is described in other cell types with characteristically low to undetectable basal expression, but is highly stress induced. Despite this response in other cells, little is known about its control in keratinocytes. We examined endogenous human keratinocyte HSPA6 expression and localized some responsible transcription factor sites in a cloned HSPA6 3?kb promoter. Using promoter 5-truncations and deletions, negative and positive regulatory regions were found throughout the 3?kb promoter. A region between ?46 and ?17?bp was found to be crucial to HSPA6 basal expression and stress inducibility. Site-specific mutations and DNA-binding studies show that a previously uncharacterized AP1 site contributes to the basal expression and maximal stress induction of HSPA6. Additionally, a new heat shock element (HSE) within this region was defined. While this element mediates increased transcriptional response in thermally stressed HaCaT keratinocytes, it preferentially binds a stress-inducible factor other than heat shock factor (HSF)1 or HSF2. Intriguingly, this newly characterized HSPA6 HSE competes HSF1 binding a consensus HSE and binds both HSF1 and HSF2 from other epithelial cells. Taken together, our results demonstrate that the HSPA6 promoter contains essential negative and positive promoter regions and newly identified transcription factor targets, which are key to the basal and stress-inducible expression of HSPA6. Furthermore, these results suggest that an HSF-like factor may preferentially bind this newly identified HSPA6 HSE in HaCaT cells.