Mycelial Propagation and Molecular Phylogenetic Relationships of Commercially Cultivated Agrocybe cylindracea Based on ITS Sequences and RAPD

Author: mycolabadmin
2010-06-30
View Source

Summary

This research studied how to best grow the black poplar mushroom (Agrocybe cylindracea) and analyzed genetic differences between strains from different Asian countries. The study determined optimal growing conditions and showed how genetically similar or different various strains are from each other. Impacts on everyday life: • Helps mushroom farmers optimize cultivation conditions for better yields • Contributes to more efficient production of this nutritious and medicinal mushroom • Aids in identifying and preserving distinct genetic strains of the mushroom • Supports development of improved mushroom varieties for consumption • Advances understanding of this mushroom’s potential health benefits

Background

Agrocybe cylindracea, known as black poplar mushroom, is a newly cultivated mushroom in East Asia that has become increasingly popular due to its delicious taste and unique texture. It is cultivated mainly on low-cost agricultural and forest waste substrates. The mushroom has demonstrated important medicinal properties including antioxidant, antimutagenic, antitumor, antifungal, hypercholesterolemic, and hyperlipidemic properties, as well as ability to decrease blood sugar and provide immuno-stimulating activities.

Objective

This study aimed to investigate the optimal culture conditions for vegetative growth and molecular phylogenetic relationships of eleven strains of Agrocybe cylindracea collected from different ecological regions of Korea, China and Taiwan. The research examined various environmental and nutritional parameters for cultivation as well as genetic relationships between strains.

Results

The optimal temperature and pH for mycelial growth were 25°C and pH 6. Potato dextrose agar and Hennerberg were the most favorable media. Dextrin, maltose and fructose were the most effective carbon sources, while arginine and glycine were the most suitable nitrogen sources. ITS sequence analysis showed 98-100% similarity between strains, with ITS2 being more variable than ITS1. RAPD analysis using 15 effective primers showed an average of 3.8 polymorphic bands per primer, with fragments ranging from 0.1 to 2.9 kb.

Conclusion

The results revealed that both RAPD and ITS techniques were well suited for detecting genetic diversity among A. cylindracea strains. The study successfully identified optimal growth conditions and demonstrated genetic relationships between strains from different geographical regions.

Published in:Mycobiology,
Study Type:Laboratory Research,
Source: 10.4489/MYCO.2010.38.2.089