Lawsonia inermis seeds cotyledon and coat extracts as a potential antimicrobial agent

Background: The plant Lawsonia inermis, which is a member of the Lythraceae family, has long been used to cure a number of diseases. Previous studies have demonstrated the antibacterial capabilities of the plant's components. However, neither the efficiency of these extracts on bacterial strains that are antibiotic-resistant nor a systematic analysis of the extracts from the various seed components have been conducted. Methods: The coat part was separated from the cotyledon. Each part was pulverized and extracted with ethanol, acetone, and hexane. The inhibitory effects of the resulting extracts were tested on three pathogenic bacterial strains and a fungus. The effect of the extracts on antibiotic-resistant bacteria was also evaluated.Results: When tested against pathogenic bacteria (Bacillus subtilis, Staphylococcus aureus, Klebsiella pneumonia, and Candida albicans), L. inermis seed parts (cotyledon and coat) showed varying levels of antibacterial and antifungal activity. In which the ethanolic extract outperformed the acetonic extract in effectiveness. The minimal inhibitory concentration (MIC) for each pathogenic microorganism was established. Utilizing the extract yield, total antibacterial activity (TAA) was calculated. Lawsonia inermis seed components inhibited antibiotic-resistant strains of S. aureus and P. aeruginosa, with strong antibacterial activity seen in aqueous extracts of their cotyledons and coats.Conclusion: We summarize that Lawsonia inermis seed extracts, which have historically been used as secure antimicrobials for human healthcare and cosmetics have the potential to replace current antimicrobial agents that are no longer effective. Moreover, may be a promising source for the isolation of potent drugs for the treatment of bacterial diseases.Keywords: Lawsonia inermis; Henna; Extract; Seeds; Bacterial Infection; Antibiotics Resistance   

Phoenix dactylifera (date palm; Arecaceae) putative lectin homologs: Genome-wide search, architecture analysis, and evolutionary relationship

The date palm, Phoenix dactylifera, is a vital crop in nations in the Middle East and North Africa. The date palm was thought to have outstanding traditional medicinal value because it was abundant in phytochemicals with diverse chemical structures. The date palm's ability to withstand harsh environments could be partly attributed to a class of proteins known as lectins, which are carbohydrate-binding proteins that can bind sugar moieties reversibly and without changing their chemical structures. After scanning the genome of P. dactylifera (GCF 009389715.1), this in silico study discovered 196 possible lectin homologs from 11 different families, some specific to plants. At the same time, others could also be found in other kingdoms of life. Their domain architectures and functional amino acid residues were investigated, and they yielded a 40% true-lectin with known conserved carbohydrate-binding residues. Further, their probable subcellular localization, physiochemical and phylogenetic analyses were also performed. Scanning all putative lectin homologs against the anticancer peptide (ACP) dataset found in the AntiCP2.0 webpage identified 26 genes with protein kinase receptors (Lec-KRs) belonging to 5 lectin families, which are reported to have at least one ACP motif. Our study offers the first account of Phoenix-lectins and their organization that can be used for further structural and functional analysis and investigating their potential as anticancer proteins