5 research outputs found

    A Platform for Determining Medicinal Plants with Targeted 17β-Hydroxysteroid Dehydrogenase Modulation for Possible Hair Loss Prevention

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    Although hair loss plays a vital physiological function in present society, their impact on shaping self-esteem is undeniable. Even though there are numerous synthetic drugs available, these days, there are issues with safety, efficiency, and unclear time settings for required outcomes with the current synthetic drug remedies available; therefore, there is growing attention to discovering alternative methods to fight hair loss, primarily through plant-derived formulations. While earlier reports mostly focused on screening compounds or plant extracts affecting 5α-reductase, our research takes a unique direction. We employed a biochemical and molecular biological approach by delving into the complicated biosynthetic pathways involving 17β-hydroxysteroid dehydrogenase (17β-HSD) and 3β-hydroxysteroid dehydrogenase (3β-HSD) in producing testosterone derived from cholesterol. This process conceded requiring experimental results, posing insights into the control of the testosterone/dihydrotestosterone (DHT) production pathway. Our study confirms a discovery platform for finding potential candidates as hair loss inhibitors, highlighting exploring various biochemical mechanisms involving 17β-HSD and 3β-HSD in combination with medicinal plant extracts

    Transcriptional profiling in human HaCaT keratinocytes in response to kaempferol and identification of potential transcription factors for regulating differential gene expression

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    Kaempferol is the major flavonol in green tea and exhibits many biomedically useful properties such as antioxidative, cytoprotective and anti-apoptotic activities. To elucidate its effects on the skin, we investigated the transcriptional profiles of kaempferol-treated HaCaT cells using cDNA microarray analysis and identified 147 transcripts that exhibited significant changes in expression. Of these, 18 were up-regulated and 129 were down-regulated. These transcripts were then classified into 12 categories according to their functional roles: cell adhesion/cytoskeleton, cell cycle, redox homeostasis, immune/defense responses, metabolism, protein biosynthesis/modification, intracellular transport, RNA processing, DNA modification/ replication, regulation of transcription, signal transduction and transport. We then analyzed the promoter sequences of differentially-regulated genes and identified over-represented regulatory sites and candidate transcription factors (TFs) for gene regulation by kaempferol. These included c-REL, SAP-1, Ahr-ARNT, Nrf-2, Elk-1, SPI-B, NF-κB and p65. In addition, we validated the microarray results and promoter analyses using conventional methods such as real-time PCR and ELISA-based transcription factor assay. Our microarray analysis has provided useful information for determining the genetic regulatory network affected by kaempferol, and this approach will be useful for elucidating gene-phytochemical interactions
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