Cloe S. Pogoda scite author profile

Symbioses among co-evolving taxa are often marked by genome reductions such as a loss of protein-coding genes in at least one of the partners as a means of reducing redundancy or intergenomic conflict. To explore this phenomenon in an iconic yet under-studied group of obligate symbiotic organisms, mitochondrial genomes of 22 newly sequenced and annotated species of lichenized fungi were compared to 167 mitochondrial genomes of nonlichenized fungi. Our results demonstrate the first broad-scale loss of atp9 from mitochondria of lichenized fungi. Despite key functions in mitochondrial energy production, we show that atp9 has been independently lost in three different lineages spanning 10 of the 22 studied species. A search for predicted, functional copies of atp9 among genomes of other symbionts involved in each lichen revealed the full-length, presumably functional copies of atp9 in either the photosynthetic algal partner or in other symbiotic fungi in all 10 instances. Together, these data yield evidence of an obligate symbiotic relationship in which core genomic processes have been streamlined, likely due to co-evolution.

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Comparative analysis of the mitochondrial genomes of six newly sequenced diatoms reveals group II introns in the barcoding region of cox1

Pogoda

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Hamsher

et al. 2018

Mitochondrial DNA Part A

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Diatoms are the most diverse lineage of algae and at the base of most aquatic food webs, but only 11 of their mitochondrial genomes have been described. Herein, we present the mitochondrial genomes of six diatom species, including: Melosira undulata, Nitzschia alba, Surirella sp., Entomoneis sp., Halamphora coffeaeformis, and Halamphora calidilacuna. Comparison of these six genomes to the 11 currently published diatom mitochondrial genomes revealed a novel ubiquitous feature block consisting of tatC-orf157-rps11. The presence of intronic retrotransposable elements in the barcoding region of cox1 in the Halamphora genomes may explain historic difficulty (especially PCR) with cox1 as a universal barcode for diatoms. Our analysis suggests that high rates of variability in number and position of introns, in many commonly used coding sequences, prevent these from being universally viable as barcodes for diatoms. Therefore, we suggest researchers examine the chloroplast and/or nuclear genomes for universal barcoding markers.

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Genome streamlining via complete loss of introns has occurred multiple times in lichenized fungal mitochondria

Pogoda

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Nadiadi

et al. 2019

Ecology and Evolution

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Reductions in genome size and complexity are a hallmark of obligate symbioses. The mitochondrial genome displays clear examples of these reductions, with the ancestral alpha‐proteobacterial genome size and gene number having been reduced by orders of magnitude in most descendent modern mitochondrial genomes. Here, we examine patterns of mitochondrial evolution specifically looking at intron size, number, and position across 58 species from 21 genera of lichenized Ascomycete fungi, representing a broad range of fungal diversity and niches. Our results show that the cox1 gene always contained the highest number of introns out of all the mitochondrial protein‐coding genes, that high intron sequence similarity (>90%) can be maintained between different genera, and that lichens have undergone at least two instances of complete, genome‐wide intron loss consistent with evidence for genome streamlining via loss of parasitic, noncoding DNA, in Phlyctis boliviensis and Graphis lineola . Notably, however, lichenized fungi have not only undergone intron loss but in some instances have expanded considerably in size due to intron proliferation (e.g., Alectoria fallacina and Parmotrema neotropicum ), even between closely related sister species (e.g., Cladonia ). These results shed light on the highly dynamic mitochondrial evolution that is occurring in lichens and suggest that these obligate symbiotic organisms are in some cases undergoing recent, broad‐scale genome streamlining via loss of protein‐coding genes as well as noncoding, parasitic DNA elements.

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Immunizing against Anogenital Cancer: HPV Vaccines

2016

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Cloe S. Pogoda

Reductions in complexity of mitochondrial genomes in lichen‐forming fungi shed light on genome architecture of obligate symbioses

Comparative analysis of the mitochondrial genomes of six newly sequenced diatoms reveals group II introns in the barcoding region of cox1

Genome streamlining via complete loss of introns has occurred multiple times in lichenized fungal mitochondria

Immunizing against Anogenital Cancer: HPV Vaccines

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