Functional relevance of bioactive compounds in purple maize: a contemporary extraction progressions and prospective applications

Purple maize (Zea mays L.), which originated in South America, has potential use in the biomedical and food industries due to its high concentration of bioactive substances which includes flavonoids, phenolic compounds and anthocyanin. The bioactive compounds have anti-angiogenesis, anti-mutagenic, anti-oxidant, anti-mutagenic, anti-carcinogenic and anti-inflammatory qualities that serve the health industries. Purple maize compounds benefit the food processing sector by affording an alternate solution to artificial colorants. Purple maize has been genetically engineered to boost the productivity of bioactive compounds by inserting several genes and employing bidirectional promoters. There are several ways for extracting bioactive chemicals from purple maize, which are classed as traditional and contemporary extraction methods. The extraction procedures were intended to suit industrial scale needs while retaining the nutritive benefits of the compounds. The review emphasizes the contemporary research on genetically altered purple maize as well as industrial scale extractions of bioactive chemicals with biomedical and food sector implications

Transcriptomic Prediction of Pig Liver-Enriched Gene 1 Functions in a Liver Cell Line

The newly identified liver-enriched gene 1 (LEG1) encodes a protein with a characteristic domain of unknown function 781 (DUF781/LEG1), constituting a protein family with only one member in mammals. A functional study in zebrafish suggested that LEG1 genes are involved in liver development, while the platypus LEG1 homolog, Monotreme Lactation Protein (MLP), which is enriched in the mammary gland and milk, acts as an antibacterial substance. However, no functional studies on eutherian LEG1s have been published to date. Thus, we here report the first functional prediction study at the cellular level. As previously reported, eutherian LEG1s can be classified into three paralogous groups. Pigs have all three LEG1 genes (pLEG1s), while humans and mice have retained only LEG1a. Hence, pLEG1s might represent an ideal model for studying LEG1 gene functions. RNA-seq was performed by the overexpression of pLEG1s and platypus MLP in HepG2 cells. Enrichment analysis showed that pLEG1a and pLEG1b might exhibit little function in liver cells; however, pLEG1c is probably involved in the endoplasmic reticulum (ER) stress response and protein folding. Additionally, gene set enrichment analysis revealed that platypus MLP shows antibacterial activity, confirming the functional study in platypus. Therefore, our study showed from the transcriptomic perspective that mammalian LEG1s have different functions in liver cells due to the subfunctionalization of paralogous genes.</jats:p

Transcriptomic Prediction of Pig Liver-Enriched Gene 1 Functions in a Liver Cell Line

The newly identified liver-enriched gene 1 (LEG1) encodes a protein with a characteristic domain of unknown function 781 (DUF781/LEG1), constituting a protein family with only one member in mammals. A functional study in zebrafish suggested that LEG1 genes are involved in liver development, while the platypus LEG1 homolog, Monotreme Lactation Protein (MLP), which is enriched in the mammary gland and milk, acts as an antibacterial substance. However, no functional studies on eutherian LEG1s have been published to date. Thus, we here report the first functional prediction study at the cellular level. As previously reported, eutherian LEG1s can be classified into three paralogous groups. Pigs have all three LEG1 genes (pLEG1s), while humans and mice have retained only LEG1a. Hence, pLEG1s might represent an ideal model for studying LEG1 gene functions. RNA-seq was performed by the overexpression of pLEG1s and platypus MLP in HepG2 cells. Enrichment analysis showed that pLEG1a and pLEG1b might exhibit little function in liver cells; however, pLEG1c is probably involved in the endoplasmic reticulum (ER) stress response and protein folding. Additionally, gene set enrichment analysis revealed that platypus MLP shows antibacterial activity, confirming the functional study in platypus. Therefore, our study showed from the transcriptomic perspective that mammalian LEG1s have different functions in liver cells due to the subfunctionalization of paralogous genes