HSPC016 Activators represent a specialized category of chemical compounds formulated to target and enhance the activity of HSPC016, a protein encoded by a gene that was identified through human genomic projects, indicating its potential involvement in cellular processes yet to be fully elucidated. The name HSPC016 suggests its initial discovery in hematopoietic stem and progenitor cell (HSPC) populations or its listing in a genomic catalog, pointing towards a possible role in cell proliferation, differentiation, or stress response mechanisms. The development of activators for HSPC016 is driven by the hypothesis that modulating this protein's function could provide insights into its biological roles and impact the cellular pathways in which it participates. These activators are synthesized through advanced chemical engineering processes, aiming to produce molecules that can specifically interact with the HSPC016 protein, potentially enhancing its natural activity within cells. This entails a comprehensive understanding of the protein's structure, including any functional domains or motifs, to design molecules capable of effectively modulating its function without undesirable off-target effects.
The exploration of HSPC016 Activators involves an interdisciplinary research approach, incorporating techniques from molecular biology, biochemistry, and computational biology to elucidate how these compounds interact with the HSPC016 protein. Scientists employ methods such as affinity binding assays, co-immunoprecipitation, and functional assays to assess the impact of these activators on the protein's activity and its interaction with other cellular components. Structural studies, including X-ray crystallography and cryo-electron microscopy, are pivotal in determining the three-dimensional structure of HSPC016, revealing potential binding sites for activators and the conformational changes associated with activation. Additionally, computational modeling and molecular docking play crucial roles in predicting the interactions between HSPC016 and potential activators, guiding the rational design and optimization of these molecules for increased specificity and potency. Through this comprehensive research framework, the study of HSPC016 Activators aims to contribute to the understanding of the HSPC016 protein's function in cellular processes, advancing the field of protein modulation and cellular regulation.
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| Product Name | CAS # | Catalog # | QUANTITY | Price | Citations | RATING |
|---|---|---|---|---|---|---|
Curcumin | 458-37-7 | sc-200509 sc-200509A sc-200509B sc-200509C sc-200509D sc-200509F sc-200509E | 1 g 5 g 25 g 100 g 250 g 1 kg 2.5 kg | $36.00 $68.00 $107.00 $214.00 $234.00 $862.00 $1968.00 | 47 | |
Curcumin is known to affect a wide range of signaling pathways, potentially influencing gene expression through transcriptional regulation. | ||||||
Resveratrol | 501-36-0 | sc-200808 sc-200808A sc-200808B | 100 mg 500 mg 5 g | $60.00 $185.00 $365.00 | 64 | |
As a polyphenolic compound, resveratrol may modulate sirtuin activity and, consequently, affect gene expression patterns. | ||||||
D,L-Sulforaphane | 4478-93-7 | sc-207495A sc-207495B sc-207495C sc-207495 sc-207495E sc-207495D | 5 mg 10 mg 25 mg 1 g 10 g 250 mg | $150.00 $286.00 $479.00 $1299.00 $8299.00 $915.00 | 22 | |
Sulforaphane can activate the Nrf2 pathway, which regulates the expression of genes involved in cellular defense mechanisms. | ||||||
Metformin | 657-24-9 | sc-507370 | 10 mg | $77.00 | 2 | |
Metformin activates AMPK, which can lead to the modulation of gene expression related to energy homeostasis and metabolic stress. | ||||||
(−)-Epigallocatechin Gallate | 989-51-5 | sc-200802 sc-200802A sc-200802B sc-200802C sc-200802D sc-200802E | 10 mg 50 mg 100 mg 500 mg 1 g 10 g | $42.00 $72.00 $124.00 $238.00 $520.00 $1234.00 | 11 | |
EGCG, the major catechin in green tea, can modulate gene expression by influencing various signaling pathways and epigenetic modifications. | ||||||
Sodium Butyrate | 156-54-7 | sc-202341 sc-202341B sc-202341A sc-202341C | 250 mg 5 g 25 g 500 g | $30.00 $46.00 $82.00 $218.00 | 19 | |
As an HDAC inhibitor, sodium butyrate can cause hyperacetylation of histones, which may result in changes in gene expression. | ||||||
β-Carotene | 7235-40-7 | sc-202485 sc-202485A sc-202485B sc-202485C | 1 g 25 g 50 g 5 kg | $68.00 $297.00 $502.00 $12246.00 | 5 | |
Beta-carotene, a precursor of vitamin A, can influence gene expression through retinoid signaling pathways after its conversion to retinol. | ||||||
Genistein | 446-72-0 | sc-3515 sc-3515A sc-3515B sc-3515C sc-3515D sc-3515E sc-3515F | 100 mg 500 mg 1 g 5 g 10 g 25 g 100 g | $26.00 $92.00 $120.00 $310.00 $500.00 $908.00 $1821.00 | 46 | |
This isoflavone, found in soybeans, can act as a phytoestrogen and potentially modulate the expression of estrogen-responsive genes. | ||||||
Quercetin | 117-39-5 | sc-206089 sc-206089A sc-206089E sc-206089C sc-206089D sc-206089B | 100 mg 500 mg 100 g 250 g 1 kg 25 g | $11.00 $17.00 $108.00 $245.00 $918.00 $49.00 | 33 | |
Quercetin may influence gene expression by modulating various signaling pathways, including those involving kinases and transcription factors. | ||||||
Kaempferol | 520-18-3 | sc-202679 sc-202679A sc-202679B | 25 mg 100 mg 1 g | $97.00 $212.00 $500.00 | 11 | |
This flavonoid is known to affect cellular signaling and potentially regulate gene expression through epigenetic mechanisms. | ||||||