Date published: 2025-10-28

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DPF1 Inhibitors

DPF1 inhibitors are a class of chemical compounds specifically designed to target and inhibit the activity of the DPF1 protein, also known as double PHD fingers 1. DPF1 is a member of the D4, zinc, and double PHD fingers family of proteins, which are known for their roles in chromatin remodeling and gene regulation. DPF1 is involved in the regulation of transcription through its ability to interact with chromatin and modify the structure of histones, the proteins around which DNA is wrapped. This interaction allows DPF1 to influence the accessibility of DNA to the transcriptional machinery, thereby playing a critical role in the control of gene expression. The double PHD fingers (plant homeodomain) in DPF1 are key domains that enable the protein to bind to specific histone marks, making it a significant regulator in epigenetic modifications. The inhibition of DPF1 by specific inhibitors typically involves binding to the PHD finger domains or other regions of the protein that are crucial for its function in chromatin remodeling. By blocking these interactions, DPF1 inhibitors can disrupt the protein's ability to alter chromatin structure, thereby affecting the transcription of genes that rely on this regulation. This inhibition can lead to changes in gene expression patterns, potentially impacting various cellular processes, including cell differentiation, proliferation, and response to environmental signals. Additionally, DPF1 inhibitors may interfere with the broader network of protein-protein interactions that DPF1 is involved in, further influencing chromatin dynamics and the regulation of the epigenetic landscape within the cell. Understanding the effects of DPF1 inhibition provides valuable insights into the complex mechanisms of chromatin remodeling and gene regulation, shedding light on the role of epigenetic factors in controlling cellular identity and function. This knowledge is crucial for comprehending how alterations in chromatin structure contribute to the regulation of gene expression and the maintenance of cellular homeostasis.

Items 1 to 10 of 12 total

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Product NameCAS #Catalog #QUANTITYPriceCitationsRATING

DAPT

208255-80-5sc-201315
sc-201315A
sc-201315B
sc-201315C
5 mg
25 mg
100 mg
1 g
$99.00
$335.00
$836.00
$2099.00
47
(3)

γ-secretase inhibitor that can inhibit Notch signaling, which is related to neural differentiation.

LY 294002

154447-36-6sc-201426
sc-201426A
5 mg
25 mg
$121.00
$392.00
148
(1)

PI3K inhibitor affecting neural differentiation pathways.

PD 98059

167869-21-8sc-3532
sc-3532A
1 mg
5 mg
$39.00
$90.00
212
(2)

Inhibits MEK, part of the ERK/MAPK signaling pathway, which can influence neural differentiation.

SU 5402

215543-92-3sc-204308
sc-204308A
1 mg
5 mg
$62.00
$96.00
36
(3)

FGFR1 inhibitor that can impact neural differentiation and growth factor signaling.

SB 431542

301836-41-9sc-204265
sc-204265A
sc-204265B
1 mg
10 mg
25 mg
$80.00
$212.00
$408.00
48
(1)

Inhibitor of the TGF-β receptor, impacting neural differentiation.

Cyclopamine

4449-51-8sc-200929
sc-200929A
1 mg
5 mg
$92.00
$204.00
19
(1)

Hedgehog signaling pathway inhibitor; can influence pathways related to neural differentiation.

Y-27632, free base

146986-50-7sc-3536
sc-3536A
5 mg
50 mg
$182.00
$693.00
88
(1)

ROCK inhibitor, known to have an effect on neural precursor cell differentiation.

U-0126

109511-58-2sc-222395
sc-222395A
1 mg
5 mg
$63.00
$241.00
136
(2)

MEK1 and MEK2 inhibitor, impacting the ERK/MAPK signaling associated with neural differentiation.

Rapamycin

53123-88-9sc-3504
sc-3504A
sc-3504B
1 mg
5 mg
25 mg
$62.00
$155.00
$320.00
233
(4)

Inhibits mTOR signaling, which can be associated with neural differentiation processes.

IWR-1-endo

1127442-82-3sc-295215
sc-295215A
5 mg
10 mg
$82.00
$132.00
19
(1)

Wnt pathway inhibitor; Wnt signaling plays a role in neural differentiation.