Scanning electron microscopy reveals deleterious effects of Moringa oleifera seed exuded proteins on root-knot nematode Meloidogyne incognita eggs.

Plant seeds can exudate active molecules with inhibitory effects against several soil pathogens, including nematodes. This study aimed to characterize and evaluate the nematicidal properties against Meloidogyne incognita of exuded proteins from Moringa oleifera seeds. M. oleifera seeds were soaked in distilled water, and exudates were harvested and analyzed for the presence of defense proteins and anthelmintic activity. Enzymatic assays revealed the existence of PR-proteins such as ß-1,3-glucanases (0.18 ± 0.003 nkatal mg-1 of protein), chitinases (0.22 ± 0.004 nkatal mg-1 of protein), proteases (261.30 ± 6.405 AU mg-1 of protein min-1), serine (190.30 ± 5.574 IA mg-1 of protein) and cysteine (231.70 ± 0.923 IA mg-1 of protein), protease inhibitors. The exuded proteins presented ovicidal activity and caused 100% mortality of second-stage juveniles (J2s). Scanning electron microscopy (SEM) revealed deleterious effects on M. incognita eggs, such as invaginations, cracks, scratched surface, and loss of internal content. These findings confirm the presence of anthelmintic proteins in M. oleifera seed exudate, possibly involved in plant defense during seed germination. Besides this, the exuded proteins exhibited strong biotechnological potential for use in the biocontrol of M. incognita infections, which are responsible for millions of dollars in staple crop losses every year.

New insights into the structure and mode of action of Mo-CBP3, an antifungal chitin-binding protein of Moringa oleifera seeds.

Mo-CBP3 is a chitin-binding protein purified from Moringa oleifera Lam. seeds that displays inhibitory activity against phytopathogenic fungi. This study investigated the structural properties and the antifungal mode of action of this protein. To this end, circular dichroism spectroscopy, antifungal assays, measurements of the production of reactive oxygen species and microscopic analyses were utilized. Mo-CBP3 is composed of 30.3% α-helices, 16.3% ß-sheets, 22.3% turns and 30.4% unordered forms. The Mo-CBP3 structure is highly stable and retains its antifungal activity regardless of temperature and pH. Fusarium solani was used as a model organism for studying the mechanisms by which this protein acts as an antifungal agent. Mo-CBP3 significantly inhibited spore germination and mycelial growth at 0.05 mg.mL-1. Mo-CBP3 has both fungistatic and fungicidal effects, depending on the concentration used. Binding of Mo-CBP3 to the fungal cell surface is achieved, at least in part, via electrostatic interactions, as salt was able to reduce its inhibitory effect. Mo-CBP3 induced the production of ROS and caused disorganization of both the cytoplasm and the plasma membrane in F. solani cells. Based on its high stability and specific toxicity, with broad-spectrum efficacy against important phytopathogenic fungi at low inhibitory concentrations but not to human cells, Mo-CBP3 has great potential for the development of new antifungal drugs or transgenic crops with enhanced resistance to phytopathogens.

A novel chitin-binding protein from Moringa oleifera seed with potential for plant disease control.

A thermostable chitin-binding protein (14.3 kDa) with antifungal activity was isolated from Moringa oleifera seeds by affinity chromatography on chitin followed by ion exchange chromatography. NH(2-) CPAIQRCCQQLRNIQPPCRCCQ (Mo-CBP3) is a glycoprotein with 2.5% sugar, pI 10.8, without hemagglutination, chitinase or beta-glucanase activities. Mo-CBP3 possesses in vitro antifungal activity against the phytopathogenicfungi Fusarium solani, F. oxysporum, Colletotrichum musae and C. gloesporioides. Contrarily, Mo-CBP3 did not affect Pythium oligandrum, an oomycete. At 0.05 mg/ml, Mo-CBP3 showed to be fungistatic against F. solani, but at 0.1 mg/ml Mo-CBP3 behaved as a potent fungicidal agent as it inhibited both the spore germination and mycelial growth of F. solani. Surprisingly, the effect of Mo-CBP3 against spore germination was observed even when the protein was heated at 100 degrees C for 1 h or pretreated with 0.15M N-acetyl-D-glucosamine. Mo-CBP3 inhibited the glucose-stimulated acidification of the incubation medium by F. solani. This is apparently caused by structural plasma membrane disarrangement induced by Mo-CBP3. Altogether, these results suggest that Mo-CBP3 might be involved in plant defense mechanisms and could be used as potential antifungal agent for controlling fungal pathogens in plants.