Transposable element clusters in the genome of Magnaporthe oryzae are positively correlated with genetic recombination, loss of synteny, increased gene duplication and increased rate of evolution.

Thon, M.R., Mitchell, T.K. and  Dean, R. 2006.   8th European Conference on Fungal Genetics (ECFG). April 7-12, 2006. Vienna, Austria.

Transposable elements (TEs) are known to be major contributors to genome 

evolution. Genome wide studies have shown that in fungi, TEs are usually 

confined to distinct clusters within the genome. To better understand the role of 

TEs in mediating genome rearrangement, gene duplication, and gene evolution, 

we performed an in depth study of chromosome 7 of the rice blast fungus 

Magnaporthe oryzae. Using chromosome 7 as a reference sequence, we 

identified 21 statistically significant blocks of conserved synteny in Neurospora 

crassa, 17 in Fusarium graminearum, and 2 in Aspergillus nidulans. In general, 

the blocks were roughly co-linear and interspersed with intervening, non- 

syntenic genes. TEs are predominantly restricted to three clusters located in 

regions that lack conserved synteny. In contradiction to popular evolutionary 

models as well as observations from other model organism genomes, we found a 

positive correlation between recombination rate and the distribution of TE 

clusters on chromosome 7. We grouped chromosome 7 genes into gene families 

and identified orthologous genes in N. crassa and F. graminearum. We found 

that the chromosomal regions defined by the TE clusters have more frequent 

gene duplications and genes within the clusters are evolving at a faster rate. 

Together, these data suggest that TEs have a profound impact on the M. oryzae 

genome by creating localized segments with increased rates of chromosomal 

rearrangements, gene duplications and gene evolution. 

 

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