Biosynthesis and Pharmacological Activities of the Bioactive Compounds of White Mulberry (Morus alba): Current Paradigms and Future Challenges.

Traditional natural products have been the focus of research to explore their medicinal properties. One such medicinally important plant is the white mulberry, Morus alba, widely distributed in the Asian subcontinent. It is one of the most cultivated species of mulberry tree and has attracted more focus from researchers because of its abundance in phytochemicals as well as multipurpose uses. The leaves, fruits and other parts of the white mulberry plant act as a source of valuable bioactive compounds like flavonoids, phenolic acids, terpenoids and alkaloids. These secondary metabolites have manifold healthy uses as they possess antioxidant, anti-inflammatory, antidiabetic, neutrotrophic, and anticancer properties. Despite the increasing scientific interest in this plant, there are very few reviews that highlight the phytochemistry and biological potential of white mulberry for biomedical research. To this end, this review elaborates the phytochemistry, biosynthetic pathways and pharmacological activities of the glycoside flavonoids of Morus alba. A comprehensive analysis of the available literature indicates that Morus alba could emerge as a promising natural agent to combat diverse conditions including diabetes, cancer, inflammation and infectious diseases. To achieve such important objectives, it is crucial to elucidate the biosynthesis and regulation mechanisms of the bioactive compounds in white mulberry as well as the multifaceted pharmacological effects attributed to this plant resource. The present review paper is intended to present a summary of existing scientific data and a guide for further research in the phytochemistry and pharmacology of white mulberry. Further, a biosynthetic pathway analysis of the glycoside flavonoid in mulberry is also given. Lastly, we discuss the pros and cons of the current research to ensure the prudent and effective therapeutic value of mulberry for promoting human and animal health.

Effects of MhMYB1 and MhMYB2 transcription factors on the monoterpenoid biosynthesis pathway in l-menthol chemotype of Mentha haplocalyx Briq.

MAIN CONCLUSION: Transcription factors MhMYB1 and MhMYB2 correlate with monoterpenoid biosynthesis pathway in l-menthol chemotype of Mentha haplocalyx Briq, which could affect the contents of ( -)-menthol and ( -)-menthone. Mentha haplocalyx Briq., a plant with traditional medicinal and edible uses, is renowned for its rich essential oil content. The distinct functional activities and aromatic flavors of mint essential oils arise from various chemotypes. While the biosynthetic pathways of the main monoterpenes in mint are well understood, the regulatory mechanisms governing different chemotypes remain inadequately explored. In this investigation, we identified and cloned two transcription factor genes from the M. haplocalyx MYB family, namely MhMYB1 (PP236792) and MhMYB2 (PP236793), previously identified by our research group. Bioinformatics analysis revealed that MhMYB1 possesses two conserved MYB domains, while MhMYB2 contains a conserved SANT domain. Yeast one-hybrid (Y1H) analysis results demonstrated that both MhMYB1 and MhMYB2 interacted with the promoter regions of MhMD and MhPR, critical enzymes in the monoterpenoid biosynthesis pathway of M. haplocalyx. Subsequent virus-induced gene silencing (VIGS) of MhMYB1 and MhMYB2 led to a significant reduction (P < 0.01) in the relative expression levels of MhMD and MhPR genes in the VIGS groups of M. haplocalyx. In addition, there was a noteworthy decrease (P < 0.05) in the contents of ( -)-menthol and ( -)-menthone in the essential oil of M. haplocalyx. These findings suggest that MhMYB1 and MhMYB2 transcription factors play a positive regulatory role in ( -)-menthol biosynthesis, consequently influencing the essential oil composition in the l-menthol chemotype of M. haplocalyx. This study serves as a pivotal foundation for unraveling the regulatory mechanisms governing monoterpenoid biosynthesis in different chemotypes of M. haplocalyx.

Mining and functional characterization of NADPH-cytochrome P450 reductases of the DNJ biosynthetic pathway in mulberry leaves.

BACKGROUND: 1-Deoxynojirimycin (DNJ), the main active ingredient in mulberry leaves, with wide applications in the medicine and food industries due to its significant functions in lowering blood sugar, and lipids, and combating viral infections. Cytochrome P450 is a key enzyme for DNJ biosynthesis, its activity depends on the electron supply of NADPH-cytochrome P450 reductases (CPRs). However, the gene for MaCPRs in mulberry leaves remains unknown. RESULTS: In this study, we successfully cloned and functionally characterized two key genes, MaCPR1 and MaCPR2, based on the transcriptional profile of mulberry leaves. The MaCPR1 gene comprised 2064 bp, with its open reading frame (ORF) encoding 687 amino acids. The MaCPR2 gene comprised 2148 bp, and its ORF encoding 715 amino acids. The phylogenetic tree indicates that MaCPR1 and MaCPR2 belong to Class I and Class II, respectively. In vitro, we found that the recombinant enzymes MaCPR2 protein could reduce cytochrome c and ferricyanide using NADPH as an electron donor, while MaCPR1 did not. In yeast, heterologous co-expression indicates that MaCPR2 delivers electrons to MaC3'H hydroxylase, a key enzyme catalyzing the production of chlorogenic acid from 3-O-p-coumaroylquinic acid. CONCLUSIONS: These findings highlight the orchestration of hydroxylation process mediated by MaCPR2 during the biosynthesis of secondary metabolite biosynthesis in mulberry leaves. These results provided a foundational understanding for fully elucidating the DNJ biosynthetic pathway within mulberry leaves.

Transcriptome analysis of transcription factors and enzymes involved in monoterpenoid biosynthesis in different chemotypes of Mentha haplocalyx Briq.

Background: The main active ingredients of Mentha haplocalyx Briq. essential oils are monoterpenes. According to the component of essential oils, M. haplocalyx can be divided into different chemotypes. Chemotype variation is widespread in Mentha plants but its formation mechanism is unclear. Methods: We selected the stable chemotype l-menthol, pulegone, and carvone of M. haplocalyx for transcriptome sequencing. To further investigate the variation of chemotypes, we analyzed the correlation between differential transcription factors (TFs) and key enzymes. Results: Fourteen unigenes related to monoterpenoid biosynthesis were identified, among which (+)-pulegone reductase (PR) and (-)-menthol dehydrogenase (MD) were significantly upregulated in l-menthol chemotype and (-)-limonene 6-hydroxylase was significantly upregulated in carvone chemotype. In addition, 2,599 TFs from 66 families were identified from transcriptome data and the differential TFs included 113 TFs from 34 families. The families of bHLH, bZIP, AP2/ERF, MYB, and WRKY were highly correlated with the key enzymes PR, MD, and (-)-limonene 3-hydroxylase (L3OH) in different M. haplocalyx chemotypes (r > 0.85). The results indicate that these TFs regulate the variation of different chemotypes by regulating the expression patterns of PR, MD, and L3OH. The results of this study provide a basis for revealing the molecular mechanism of the formation of different chemotypes and offer strategies for effective breeding and metabolic engineering of different chemotypes in M. haplocalyx.

Molecular cloning, expression, and functional analysis of copper amine oxidase gene from mulberry (Morus alba L.).

In this study, we investigated a key enzyme encoded by the gene copper amine oxidase (MaCAO), which is involved in the biosynthetic pathway of 1-deoxynojirimycin (DNJ)1, an active ingredient in mulberry leaves. The 1680 bp long MaCAO was successfully cloned (GenBank accession no: MH205733). Subsequently, MaCAO was heterologously expressed using a recombinant plasmid, pET-22b (+)/MaCAO in Escherichia coli BL21 (DE3). A protein with a molecular mass of 62.9 kDa was obtained, whose function was validated through enzymatic reaction. Bioinformatics analysis identified that MaCAO contained the same conserved domain as that of copper amine oxidases ("NYDY"). Furthermore, the tertiary structure of the predicted protein using homology modeling revealed 46% similarity with that of copper amine oxidase (Protein Data Bank ID: 1W2Z). Gas chromatography-mass spectrometry analysis of the enzymatic reaction revealed that MaCAO could catalyze 1,5-pentanediamine to produce 5-aminopentanal. Additionally, levels of mulberry leaf DNJ content were significantly positively correlated with expression levels of MaCAO (P < 0.001). Our results conclude that MaCAO is the key enzyme involved in the biosynthetic pathway of DNJ. The function of MaCAO is validated, providing a foundation for the further analysis of biosynthetic pathways of DNJ in mulberry leaves using tools of synthetic biology.

Screening, cloning and functional characterization of key methyltransferase genes involved in the methylation step of 1-deoxynojirimycin alkaloids biosynthesis in mulberry leaves.

MAIN CONCLUSION: The novel C-methyltransferase, MaMT1, could catalyze the conversion of piperidine to 2-methylpiperidine, which may be involved in the methylation step of DNJ biosynthesis in mulberry leaves. Mulberry (Morus alba L.) is a worldwide crop with medicinal, feeding and nutritional value, and 1-deoxynojirimycin ((2R, 3R, 4R, 5S)-2-hydroxymethyl-3, 4, 5-trihydroxypiperidine, DNJ) alkaloid, a potent α-glucosidase inhibitor, is its main active ingredient. Our previous researches clarified the biosynthetic pathway of DNJ from lysine to Δ1-piperideine, but its downstream pathway is unclear. Herein, eight differential methyltransferases (MTs) genes were screened from transcriptome profiles of mulberry leaves with significant differences in DNJ content (P < 0.01). Subsequently, MaMT1 (OM140666) and MaMT2 (OM140667) were hypothesized as candidate genes related to DNJ biosynthesis by correlation analysis of genes expression levels and DNJ content of mulberry leaves at different dates. Functional characterization of MaMT1 and MaMT2 were performed by cloning, prokaryotic expression and enzymatic reaction in vitro, and it showed that MaMT1 protein could catalyze the conversion of piperidine to 2-methylpiperidine. Moreover, molecular docking confirmed the interaction of MaMT1 protein with piperidine and S-adenosyl-L-methionine (SAM), indicating that MaMT1 had C-methyltransferase activity, while MaMT2 did not. The above results suggested that MaMT1 may be involved in the methylation step of DNJ alkaloid biosynthesis in mulberry leaves, which is a breakthrough in the analysis of DNJ alkaloid biosynthetic pathway. It is worth mentioning that the novel MaMT1, annotated as serine hydroxymethyltransferase, could rely on SAM to perform C-methyltransferase function. Therefore, our findings contribute new insights into the research of DNJ alkaloid biosynthesis and C-methyltransferase family.

[Identification of Cordyceps cicadae and Tolypocladium dujiaolongae based on ITS sequences and chemical pattern recognition method].

Based on ITS sequences, the molecular identification of Cordyceps cicadae and Tolypocladium dujiaolongae was carried out, and high-performance liquid chromatography(HPLC) fingerprint combined with chemical pattern recognition method was established to differentiate C. cicadae from its adulterant T. dujiaolongae. The genomic DNA from 10 batches of C. cicadae and five batches of T. dujiaolongae was extracted, and ITS sequences were amplified by PCR and sequenced. The stable differential sites of these two species were compared and the phylogenetic tree was constructed via MEGA 7.0. HPLC was used to establish the fingerprints of C. cicadae and T. dujiaolongae, and similarity evaluation, cluster analysis(CA), principal component analysis(PCA), and partial least squares discriminant analysis(PLS-DA) were applied to investigate the chemical pattern recognition. The result showed that the sources of these two species were different, and there were 115 stable differential sites in ITS sequences of C. cicadae and T. dujiao-longae. The phylogenetic tree could distinguish them effectively. HPLC fingerprints of 18 batches of C. cicadae and 5 batches of T. dujiaolongae were established. The results of CA, PCA, and PLS-DA were consistent, which could distinguish them well, indicating that there were great differences in chemical components between C. cicadae and T. dujiaolongae. The results of PLS-DA showed that six components such as uridine, guanosine, adenosine, and N~6-(2-hydroxyethyl) adenosine were the main differential markers of the two species. ITS sequences and HPLC fingerprint combined with the chemical pattern recognition method can serve as the identification and differentiation methods for C. cicadae and T. dujiaolongae.

Comparative analysis of chemical constituents by HPLC-ESI-MSn and antioxidant activities of Dendrobium huoshanense and Dendrobium officinale.

Dendrobium huoshanense is a Chinese medicinal herb that has high quality and excellent efficacy. However, the chemical basis of its activity is still unclear. Of note, Dendrobium officinale is the most widely utilized among the Dendrobium species. Therefore, the current study systematically investigated the chemical constituents of methanolic extracts and different polar fractions of aqueous extracts from the two herbs by HPLC-ESI-MSn , and then compared in vitro antioxidant activities of their five different polar extracts. Consequently, 61 and 49 compounds were identified from D. huoshanense and D. officinale, respectively, of which 43 compounds were common to both species. In addition, 17 out of 22 different compounds were identified only in D. huoshanense. Moreover, the peak areas of some shared identical compounds of D. huoshanense were significantly larger than that of D. officinale. In vitro antioxidant evaluation results showed that the n-BuOH-soluble fraction of the two herbs exhibited remarkable antioxidant activities. Furthermore, the antioxidant activities of different fractions of D. huoshanense were separately superior to that of D. officinale, which may be attributed to its variable and high contents of flavonoids, bibenzyls and phenanthrenes. These results provide the evidence for the high quality and efficacy of D. huoshanense.

In Vivo Functional Verification of Four Related Genes Involved in the 1-Deoxynojirimycin Biosynthetic Pathway in Mulberry Leaves.

The alkaloid 1-deoxynojirimycin (DNJ) is one of the major bioactive compounds in mulberry leaves (Morus alba L.). Previously, we discovered four key genes involved in the pathway from lysine to piperidine in the biosynthesis of DNJ in mulberry leaves, MaLDC (MG727866), MaCAO (MH205733), MaSDR1 (MT989445), and MaSDR2 (MT989446), which encoded lysine decarboxylase, copper amine oxidase, and short-chain dehydrogenase/reductase 1 and 2, respectively. However, the in vivo functions of these four genes have not been verified yet. Here, these four genes were successfully cloned and used for the establishment of C58C1 Agrobacterium rhizogenes mediated overexpression genetic transformation systems and GV3101 Agrobacterium-mediated virus-induced gene silencing transformation systems in order to verify the influence of these four genes on the biosynthetic content of DNJ in mulberry leaves. The results showed that the content of DNJ increased after the four genes were overexpressed. When these four genes were silenced, the gene expression was blocked, which affected the biosynthesis of DNJ, and the DNJ content decreased. The above results indicated that these four genes participated in DNJ biosynthesis. This study provided a foundation for further elucidating the regulatory mechanisms of DNJ biosynthesis in mulberry leaves.

[Herbal textual research on Rubi Fructus].

Rubi Fructus is a commonly used traditional Chinese medicine. The origin of Rubi Fructus is the dried fruit of Rubus chingii, a plant of the family Rosaceae, according to the 2015 edition of Chinese pharmacopoeia. There are some differences in the plant origin of Rubi Fructus in ancient herbal literature, to trace back its sources, we conducted a textual research on its origin, producing areas, quality evaluation, processing and concocting, properties, tastes and efficacy etc. based on the records of ancient herbal literatures and combined with plant morphology and related investigation. RESULTS:: showed that the variety of Rubi Fructus was more complex among ancient herbal literature, including R. coreanus, R. hirsutus, R. corchorifolius, R. foliolosus and other mixed varieties. Most scholars believe that the R. chingii has not been recorded in ancient herbal literature, while R. chingii was recorded as early as the Ming Dynasty in Compendium of materia medica through our textual research. Ancient Chinese herbs recorded that Rubi Fructus was mostly produced in Hubei, Shandong, Shanxi and Jiangsu provinces, while R. chingii mainly produced in Anhui, Jiangsu, Zhejiang, Jiangxi, Fujian and other provinces nowadays. Also, it was recorded that Rubi Fructus harvested in wheat field during May were the best. Besides, R. chingii with big, full, grain integrate, firm, yellow and green color, sour taste and impurity free possess the best quality in the contemporary. The ancient records of processing and concocting, properties, tastes and efficacy were basically the same as modern ones.These results provide the basis for the correct utilization and further development of Rubi Fructus.

[Systematic analysis on chemical constituents of Mori Cortex, mulberry root bark and its phellem layer based on HPLC-ESI-MS].

In this study, HPLC-ESI-MS and HPLC methods were established to explore the differences in the main chemical components and content of Mori Cortex with(mulberry root bark) and without(Mori Cortex) the phellem layer from both qualitative and quantitative aspects. The HPLC-ESI-MS method was used for quality analysis in positive and negative ion modes, and 33 compounds were identified in mulberry root bark, 22 compounds in Mori Cortex, and 26 compounds in phellem layer; mulberry root bark and Mori Cortex shared 22 components, and mulberry root bark has 11 unique compounds; Mori Cortex and its phellem layer shared 15 components, while Mori Cortex has 7 unique compounds. HPLC method was used to simultaneously determine 7 major constituents, including mulberroside A, chlorogenic acid, dihydromorin, oxyresveratrol, moracin O, kuwanon G, and kuwanon H, and the developed method showed good linearity(r>0.998 9) within the concentration range and the recoveries varied from 99.88% to 103.0%, and the RSD was 1.7%-2.9%. The HPLC results showed that the contents of the 7 compounds have great differences in 13 batches samples, compared with mulberry root bark, the contents of mulberroside A, chlorogenic acid, dihydromorin and moracin O of Mori Cortex were increased, while the contents of oxyresveratrol, kuwanon G and kuwanon H were decreased after peeling process. These results can provide a basis for the rationality and quality control of Mori Cortex required to remove the phellem layer.

Comparative Transcriptome Analysis of Key Reductase Genes Involved in the 1-Deoxynojirimycin Biosynthetic Pathway in Mulberry Leaves and Cloning, Prokaryotic Expression, and Functional Analysis of MaSDR1 and MaSDR2.

The alkaloid 1-deoxynojirimycin (DNJ) is the main bioactive ingredient in the hypoglycemic action of mulberry leaves (Morus alba L.). Our previous research clarified the upstream pathway from lysine to Δ1-piperideine in the biosynthesis of DNJ in mulberry leaves, but the pathway and related reductase genes from Δ1-piperideine to piperidine are still unclear. Here, a comparative transcriptome was used to analyze the transcriptome data of two samples (July and November) of mulberry leaves with significant differences in the content of DNJ and screen-related reductase genes. Results showed that expression levels of MaSDR1 and MaSDR2 were significantly and positively correlated with the content of DNJ (P < 0.05) in different seasons. MaSDR1 (GenBank accession no. MT989445) and MaSDR2 (GenBank accession no. MT989446) were successfully cloned and used for prokaryotic expression and functional analysis in vitro. MaSDR1 and MaSDR2 could catalyze the reaction of Δ1-piperideine with the coenzyme NADPH to generate piperidine. The kinetic parameters of MaSDR1 and MaSDR2 indicated that MaSDR2 had a higher binding ability to Δ1-piperideine than MaSDR1. This study provided insights into the biosynthesis of DNJ in mulberry leaves.