Research Keyword: histone methylation

PRMT5 promotes cellulase production by regulating the expression of cellulase gene eg2 through histone methylation in Ganoderma lucidum

mycolabadmin

Scientists discovered that a protein called PRMT5 helps mushrooms (Ganoderma lucidum) produce more cellulase enzymes, which break down plant materials like corn straw and corn cobs. By controlling a specific gene called eg2 through a chemical modification on histone proteins, PRMT5 increases enzyme production. This discovery could help industries produce cellulase more efficiently and sustainably convert agricultural waste into useful sugars for biofuels and other products.

Read More »

PRMT5 promotes cellulase production by regulating the expression of cellulase gene eg2 through histone methylation in Ganoderma lucidum

mycolabadmin

Scientists discovered that a protein called PRMT5 controls how much cellulase enzyme the medicinal mushroom Ganoderma lucidum produces. When PRMT5 activates a specific gene called eg2 through a molecular modification of histone proteins, the mushroom produces more cellulase. This enzyme is valuable for breaking down plant waste into useful sugars for industrial and bioenergy applications. This research could help develop better enzyme-producing strains for industries that need cellulase.

Read More »

PRMT5 promotes cellulase production by regulating the expression of cellulase gene eg2 through histone methylation in Ganoderma lucidum

mycolabadmin

Scientists discovered that a protein called PRMT5 in Ganoderma lucidum mushroom plays a key role in producing cellulase enzymes that break down plant cellulose. By controlling a specific gene (eg2) through a process called histone methylation, PRMT5 increases cellulase production. This finding could help develop more efficient ways to convert agricultural waste like corn straw into useful sugars for biofuels and other industrial products.

Read More »

Identification and functional analysis of the SET domain-containing gene family in Cordyceps militaris

mycolabadmin

Researchers identified 22 genes in the medicinal fungus Cordyceps militaris that control how genetic information is accessed through histone modifications. By studying how these genes respond to salt and amino acid treatments, they found that two specific genes (CmSET14 and CmSET16) are linked to cordycepin production, a compound with potential anti-cancer properties. When these genes were enhanced in the fungus, cordycepin production increased significantly, offering a new strategy to boost production of this valuable medicinal compound.

Read More »

Polyamine Induction of Secondary Metabolite Biosynthetic Genes in Fungi Is Mediated by Global Regulator LaeA and α-NAC Transcriptional Coactivator: Connection to Epigenetic Modification of Histones

mycolabadmin

Polyamines are natural compounds that act like chemical switches controlling how fungi produce useful medicines like antibiotics and statins. These molecules work by attaching to DNA and modifying histone proteins, which turns on or off the genes responsible for making pharmaceutical compounds. This research reveals that understanding polyamine control could help scientists increase antibiotic production and make plants more resistant to fungal diseases.

Read More »
Scroll to Top