Impact of a homing intein on recombination frequency and organismal fitness

Naor, Adit; Altman-Price, Neta; Soucy, Shannon M.; Green, Anna G.; Mitiagin, Yulia; Turgeman-Grott, Israela; Davidovich, Noam; Gogarten, J. Peter; Gophna, Uri

doi:10.1073/pnas.1606416113

Cited by 39 publications

(38 citation statements)

References 55 publications

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“…This is likely the case for some MGEs and lysogenic viruses, what we call ‘infectious’ genes, which are most likely deleterious but gained at high rates. For example, deleterious polymorphisms can become prevalent in a bacterial population due to the effect of high recombination mediated by conjugative plasmids 32 , and inteins with high fitness costs seem to be maintained in genomes 33 .…”

Section: Discussionmentioning

confidence: 99%

Selection-based model of prokaryote pangenomes

Domingo-Sananes

McInerney

2019

Preprint

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10The genomes of different individuals of the same prokaryote species can vary widely in gene 11 content, displaying different proportions of core genes, which are present in all genomes, and 12 accessory genes, whose presence varies between genomes. Together, these core and 13 accessory genes make up a species' pangenome. The reasons behind this extensive diversity 14 in gene content remain elusive, and there is an ongoing debate about the contribution of 15 accessory genes to fitness, that is, whether their presence is on average advantageous, 16 neutral, or deleterious. In order to explore this issue, we developed a mathematical model to 17 simulate the gene content of prokaryote genomes and pangenomes. Our model focuses on 18 testing how the fitness effects of genes and their rates of gene gain and loss would affect the 19 properties of pangenomes. We first show that pangenomes with large numbers of low-20 frequency genes can arise due to the gain and loss of neutral and nearly neutral genes in a 21 population. However, pangenomes with large numbers of highly beneficial, low-frequency 22 genes can arise as a consequence of genotype-by-environment interactions when multiple 23 niches are available to a species. Finally, pangenomes can arise, irrespective of the fitness 24 effect of the gained and lost genes, as long as gene gain and loss rates are high. We argue 25 that in order to understand the contribution of different mechanisms to pangenome diversity, 26it is crucial to have empirical information on population structure, gene-by-environment 27 interactions, the distributions of fitness effects and rates of gene gain and loss in different 28 prokaryote groups. 30 42 43Pangenomes arise as a consequence of gene acquisition via horizontal gene transfer (HGT), 44 and gene loss 2 . These processes ultimately result in general patterns observed across 45 prokaryotes, which include an increase in the number of known accessory genes as more 46 genomes from the same species are sequenced -along with a slower decrease in the number 47 of core genes-and a U-shaped gene frequency distribution or spectrum 2,10,11 . The U shape 48 2 of this distribution indicates that there is a large proportion of genes present in a single or very 49 few genomes, few genes present at intermediate frequencies, and substantial proportion of 50 core genes. Although across prokaryotic life there is a certain amount of commonality in the 51 shape of the gene content frequency distributions, different prokaryote species manifest 52 significant differences in the proportions of core and accessory genes [12][13][14] . 54Although we know that HGT and gene loss result in pangenomes, what is less clear are the 55 forces that lead to high diversity in gene content and U-shaped gene frequency distributions. 56According to mathematical models, gain and loss of entirely neutral genes along a simulated 57 phylogeny or population can in principle predict the U-shaped gene frequency distributions of 58 pangenomes 11,15 . However, the fit to real data i...

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Section: Discussionmentioning

confidence: 99%

Selection-based model of prokaryote pangenomes

Domingo-Sananes

McInerney

2019

Preprint

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“…Found in approximately one-quarter of bacterial and one-half of archaeal genomes (Novikova et al 2016), inteins have been considered as purely selfish elements (Naor et al 2016). However, 70% of inteins occur in ATP-binding proteins (Novikova et al 2016), and splicing can be regulated by environmental stresses (Callahan et al 2011;Topilina et al 2015a,b;Reitter et al 2016), suggesting that some inteins have evolved to regulate host protein function.…”

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confidence: 99%

Protein splicing of a recombinase intein induced by ssDNA and DNA damage

2016

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Inteins (or protein introns) autocatalytically excise themselves through protein splicing. We challenge the longconsidered notion that inteins are merely molecular parasites and posit that some inteins evolved to regulate host protein function. Here we show substrate-induced and DNA damage-induced splicing, in which an archaeal recombinase RadA intein splices dramatically faster and more accurately when provided with ssDNA. This unprecedented example of intein splicing stimulation by the substrate of the invaded host protein provides compelling support in favor of inteins acting as pause buttons to arrest protein function until needed; then, an immediate activity switch is triggered, representing a new form of post-translational control.

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“…Inteins, also called protein introns, are parasitic genetic elements that excise themselves at the protein level by self-splicing, allowing the formation of functional, nondisrupted proteins [37]. These data suggest that its functions may be regulated by posttranslational modi cation.…”

Section: Discussionmentioning

confidence: 99%

Eimeria tenella Eimeria-specific protein that interacts with apical membrane antigen 1 (EtAMA1) is involved in host cell invasion

Cong

Zhao

Zhu

et al. 2020

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Background: Avian coccidiosis is a widespread, economically significant disease of poultry, caused by several species of the protozoan parasite Eimeria. Among these species, E. tenella causes hemorrhagic pathologies and high mortality. These parasites have complex and diverse lifestyles that require the invasion of their host cells. This is mediated by various proteins secreted from apical secretory organelles. Apical membrane antigen 1 (AMA1), which is released from micronemes and is conserved across all apicomplexans, plays a central role in the host cell invasion. In a previous study, some putative EtAMA1-interacting proteins of E. tenella were screened. In this study, we characterized one putative EtAMA1-interacting protein, E. tenella Eimeria -specific protein (EtEsp).Methods: Bimolecular fluorescence complementation (BiFC) and glutathione S-transferase (GST) fusion protein pull-down (GST pull-down) were used to confirm the interaction between EtAMA1 and EtEsp in vivo and in vitro. The expression of EtEsp was analyzed in different developmental stages of E. tenella with quantitative PCR and western blotting. The secretion of EtEsp protein was tested with staurosporine when sporozoites were incubated in complete medium at 41 °C.The localization of EtEsp was analyzed with an immunoﬂuorescence assay. An in vitro invasion inhibition assay was conducted to assess the ability of antibodies against EtEsp to inhibit cell invasion by E. tenella sporozoites.Results: The interaction between EtAMA1 and EtEsp was confirmed with BiFC in vivo and by GST pull-down in vitro. Our results show that EtEsp is differentially expressed during distinct phases of the parasite life cycle. An immunoﬂuorescence analysis showed that the EtEsp protein is mainly distributed on the parasite surface, and that the expression of this protein increases during the development of the parasite in the host cells. Using staurosporine, we showed that EtEsp is a secreted protein, but not from micronemes. In inhibition tests, a polyclonal anti-rEtEsp antibody attenuated the capacity of E. tenella to invade host cells in vitro. Conclusion: In this study, we show that EtEsp interacts with EtAMA1 and that the protein is secreted protein, but not from micronemes. The protein participates in the sporozoite invasion of host cells and maybe involved in the growth of the parasite in the host. These data have implications for the use of EtAMA1 or EtAMA1-interacting proteins as targets in intervention strategies against avian coccidiosis.

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Impact of a homing intein on recombination frequency and organismal fitness

Cited by 39 publications

References 55 publications

Selection-based model of prokaryote pangenomes

Selection-based model of prokaryote pangenomes

Protein splicing of a recombinase intein induced by ssDNA and DNA damage

Eimeria tenella Eimeria-specific protein that interacts with apical membrane antigen 1 (EtAMA1) is involved in host cell invasion

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