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. 2019 Oct 10;10:15. doi: 10.1186/s43008-019-0015-5

Proposal of a new nomenclature for introns in protein-coding genes in fungal mitogenomes

Shu Zhang 1, Yong-Jie Zhang 2,
PMCID: PMC7325650  PMID: 32647619

Abstract

Fungal mitochondrial genes are often invaded by group I or II introns, which represent an ideal marker for understanding fungal evolution. A standard nomenclature of mitochondrial introns is needed to avoid confusion when comparing different fungal mitogenomes. Currently, there has been a standard nomenclature for introns present in rRNA genes, but there is a lack of a standard nomenclature for introns present in protein-coding genes. In this study, we propose a new nomenclature system for introns in fungal mitochondrial protein-coding genes based on (1) three-letter abbreviation of host scientific name, (2) host gene name, (3), one capital letter P (for group I introns), S (for group II introns), or U (for introns with unknown types), and (4) intron insertion site in the host gene according to the cyclosporin-producing fungus Tolypocladium inflatum. The suggested nomenclature was proved feasible by naming introns present in mitogenomes of 16 fungi of different phyla, including both basal and higher fungal lineages although minor adjustment of the nomenclature is needed to fit certain special conditions. The nomenclature also had the potential to name plant/protist/animal mitochondrial introns. We hope future studies follow the proposed nomenclature to ensure direct comparison across different studies.

Electronic supplementary material

The online version of this article (10.1186/s43008-019-0015-5) contains supplementary material, which is available to authorized users.

Keywords: Nomenclature, Fungi, Mitogenome, Intron, Protein-coding gene

INTRODUCTION

Fungi constitute a huge group of highly diverse organisms, with 2.2–3.8 million estimated species and 144,000 currently known species on Earth (Hawksworth and Lücking 2017; Cannon et al. 2018). They were traditionally divided into four groups: chytridiomycetes, zygomycetes, ascomycetes, and basidiomycetes according to morphological traits associated with reproduction. Molecular phylogenetics and more recently phylogenomics recognized eight phyla in Fungi, namely Microsporidia, Cryptomycota, Blastocladiomycota, Chytridiomycota, Zoopagomycota, Mucoromycota, Ascomycota, and Basidiomycota (Spatafora et al. 2017). Aside from a few early divergent lineages and anaerobic organisms, almost all fungi contain mitochondria and mitogenomes in their cells (Bullerwell and Lang 2005; van der Giezen et al. 2005). Over recent years, mitogenomes of an increasing number of fungal species are sequenced. As of July 2019, mitogenomes from at least 300 fungal species are available with representatives from all major fungal groups. Fungal mitogenomes typically contain 15 standard protein-coding genes, two rRNA genes and a variable number of tRNA genes. These protein-coding genes are atp6, atp8, atp9, cob, cox1, cox2, cox3, nad1, nad2, nad3, nad4, nad4L, nad5, nad6, and rps3 (Lang 2018), and some of them may be absent from certain fungal mitogenomes (Koszul et al. 2003).

Introns as mobile elements are frequently observed in mitochondrial protein-coding and/or rRNA genes of fungi. One gene may also be simultaneously invaded by multiple introns (e.g., four introns in cob and seven introns in cox1 in Isaria cicadae) (Fan et al. 2019). Mitochondrial introns are divided into two groups (I and II) based on their secondary structure and splicing mechanism (Saldanha et al. 1993), with group I introns being abundant in fungal mitogenomes. Different fungal species or even different individuals of a particular fungus may show diversity in number and insertion position of mitochondrial introns (Kosa et al. 2006; Zhang et al. 2015; Zhang et al. 2017a; Wang et al. 2018; Fan et al. 2019; Nie et al. 2019). Introns contribute to fungal mitogenome expansion/variability and represent an ideal marker for understanding fungal evolution (Zhang et al. 2015).

Currently, there has been a nomenclature for introns present in rRNA genes (Johansen and Haugen 2001). According to the nomenclature, introns are often found at a limited number of insertion sites in highly conserved regions of rRNA genes from nuclei, mitochondria, and chloroplasts, and therefore, a given rRNA sequence can be aligned with the chosen standard rRNA sequences of Escherichia coli to locate and name potential introns. For mitochondrial protein-coding genes, however, it is difficult to align their sequences with corresponding E. coli sequences due to high sequence divergence. In most literatures, introns in protein-coding genes are generally named serially according to their appearance in a particular host gene (e.g., cox1-i1, cox1-i2, and cox1-i3) (Deng et al. 2016; Zhang et al. 2017b; Zhang et al. 2017c). This naming strategy is not convenient for scientific communication and comparison of introns across different mitogenomes. A standard nomenclature of mitochondrial introns is needed to avoid confusion when comparing different fungal mitogenomes.

In our previous studies, we have tried to designate introns based on their insertion positions, but a mitogenome is arbitrarily selected from species under investigation (Fan et al. 2019; Zhang et al. 2019). In this study, we aim to propose a standard nomenclature for introns in protein-coding genes in fungal mitogenomes and test its applicability using fungal species from a broad range of taxonomic classification. To know if the suggested nomenclature can apply to “cross-kingdom” mitochondrial introns, some plant/protist/animal introns are also examined.

METHODS

In order to establish a standard nomenclature for introns in protein-coding genes across the kingdom Fungi, it is necessary to find an appropriate reference mitogenome. By looking at fungal species with available mitogenomes, we choose the mitogenome of the cyclosporin-producing fungus Tolypocladium inflatum ARSEF 3280 (accession number NC_036382) as the reference mitogenome. The 25,328-bp mitogenome of T. inflatum contains all the 15 protein-coding genes typically found in fungal mitogenomes, and there is no intron in any of these protein-coding genes (Zhang et al. 2017d). We did not choose the best-understood model fungi: ‘baker’s yeast’ Saccharomyces cerevisiae, the fission yeast Schizosaccharomyces pombe, the opportunistic fungal pathogen Candida albicans, the filamentous euascomycete Neurospora crassa, etc. This is because the yeasts Sa. cerevisiae and Sc. pombe both lack genes coding for NADH dehydrogenases in their mitogenomes (Foury et al. 1998), and C. albicans and N. crassa contain introns in many different protein-coding genes (Borkovich et al. 2004; Bartelli et al. 2013). We also did not choose the human mitochondrial genome, which was selected as the reference to name introns found in nad5 and cox1 in certain metazoans (Emblem et al. 2011). This is because the human mitogenome contains only 13 standard protein-coding genes without atp9 and rps3. The latter two genes are known to harbor introns in fungal mitogenomes.

Both basal and higher fungi may contain introns in their mitogenomes. We randomly selected representative species in each fungal phylum to locate and name possible introns (Table 1). Determination of the insertion position of an intron relies on alignment between sequences of its host gene and corresponding gene sequences of T. inflatum (Additional file 1). Although there are many sequence alignment programs available, we recommend using MAFFT (https://mafft.cbrc.jp/alignment/software/), which is fast when aligning long sequences containing many introns and can always generate satisfactory alignment according to our experience. The default setting of MAFFT works well in most cases. If exon-intron boundaries are not correctly identified (probably due to the interference of intron sequences or presence of short exons) under the default settings, one may consider adjusting the alignment parameters (e.g., try ‘Unalignlevel > 0’ and possibly ‘Leave gappy regions’ by selecting the G-INS-1 or G-INS-i alignment strategy) and/or importing additional sequences to align from a species closely related the test species. In addition, it is always advisable to refer to known annotation results and/or characteristic nucleotides at splice sites of group I/II introns (Cech 1988) to ensure correct alignment and identification of exon-intron boundaries.

Table 1.

Selected fungal species and their mitogenome information

Fungal taxa Accession Length (nt) Phylum Class Order Family Code
Basal fungi
Rozella allomycis NC_021611 12,055 Cryptomycota 4
Rhizopus oryzae NC_006836 54,178 Mucoromycota Mucorales Rhizopodaceae 1
Conidiobolus heterosporus MK049352 53,364 Zoopagomycota Entomophthoromycetes Entomophthorales Ancylistaceae 4
Allomyces macrogynus NC_001715 57,473 Blastocladiomycota Blastocladiomycetes Blastocladiales Blastocladiaceae 4
Hyaloraphidium curvatum NC_003048 29,593 Chytridiomycota Monoblepharidomycetes Monoblepharidales 4
Higher fungi
Candida albicans NC_002653 40,420 Ascomycota Saccharomycetes Saccharomycetales Debaryomycetaceae 4
Grosmannia piceiperda a FJ717837 2928 Ascomycota Sordariomycetes Ophiostomatales Ophiostomataceae
Isaria cicadae MH922223 56,581 Ascomycota Sordariomycetes Hypocreales Cordycipitaceae 4
Neurospora crassa NC_026614 64,840 Ascomycota Sordariomycetes Sordariales Sordariaceae 4
Saccharomyces cerevisiae NC_001224 85,779 Ascomycota Saccharomycetes Saccharomycetales Saccharomycetaceae 3
Schizosaccharomyces pombe NC_001326 19,431 Ascomycota Schizosaccharomycetes Schizosaccharomycetales Schizosaccharomycetaceae 4
Tolypocladium inflatum NC_036382 25,328 Ascomycota Sordariomycetes Hypocreales Ophiocordycipitaceae 4
Cryptococcus neoformans NC_004336 24,874 Basidiomycota Tremellomycetes Tremellales Tremellaceae 4
Puccinia striiformis NC_039655 101,521 Basidiomycota Pucciniomycetes Pucciniales Pucciniaceae 4
Tilletia indica NC_009880 65,147 Basidiomycota Exobasidiomycetes Tilletiales Tilletiaceae 4
Tricholoma matsutake NC_028135 76,037 Basidiomycota Agaricomycetes Agaricales Tricholomataceae 4
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a For Grosmannia piceiperda, only sequences of the rnl gene are known. In this species, an rnl group IA intron (mL2449) encodes an rps3 gene which is further fragmented by the insertion of a group IC2 intron (Rudski and Hausner 2012)

RESULTS AND DISCUSSION

We propose a new nomenclature system for introns in fungal mitochondrial protein-coding genes based on (1) three-letter abbreviation of host scientific name, (2) host gene name, (3) one capital letter P (for group I introns, meaning position or primary for easy memorization), S (for group II introns, meaning site or secondary), or U (for introns with unknown types), and (4) intron insertion site in the host gene according to T. inflatum (Additional file 1). When there is no ambiguity (e.g., when just talking about introns in a particular species or in a particular host gene of a species), host scientific name and/or host gene name may be omitted. In any case, however, the letter P/S/U and insertion site of an intron should never be omitted. Using the nomenclature, previously reported introns could be renamed. Examples of renaming are the group II intron Sce.cox1S169 (former aI1) from Saccharomyces cerevisiae cox1 at site 169, and the group I intron Cgl.cox1P240 (former CgCox1.1) from Candida glabrata cox1 at position 240. Other examples are included in Table 2 (lines 1–10). We hope future studies follow this proposed nomenclature to ensure direct comparison across different studies.

Table 2.

Representative examples of the new nomenclature of introns in protein-coding genes a

Line New name Old name Fungal taxa Host gene Accession Note Reference
1 Sce.cox1S169 aI1 Saccharomyces cerevisiae cox1 NC_001224 Group II intron Foury et al. 1998
2 Sce.cox1P971 aI5α Saccharomyces cerevisiae cox1 NC_001224 Group I intron Foury et al. 1998
3 Sce.cox1P1107 aI5β Saccharomyces cerevisiae cox1 NC_001224 Group I intron Foury et al. 1998
4 Sce.cox1S1132 aI5ɣ Saccharomyces cerevisiae cox1 NC_001224 Group II intron Foury et al. 1998
5 Cgl.cox1P240 CgCox1.1 Candida glabrata cox1 NC_004691 Group I intron Koszul et al. 2003
6 Cgl.cox1P386 CgCox1.2 Candida glabrata cox1 NC_004691 Group I intron Koszul et al. 2003
7 Cgl.cox1P971 CgCox1.3 Candida glabrata cox1 NC_004691 Group I intron Koszul et al. 2003
8 Cme.cobP393 bI1 Candida metapsilosis cob NC_006971 Group I intron Kosa et al. 2006
9 Hth.nad1P636 nad1-i1 Hirsutella thompsonii nad1 NC_040165 Group I intron Wang et al. 2018
10 Ici.atp9P181 atp9-i1 Isaria cicadae atp9 MH922223 Group I intron Fan et al. 2019
11 Cpse.nad5U717 Candida pseudojiufengensis nad5 NC_022156 Unknown intron type Unpublished
12 Cpsy.nad5P717 Candida psychrophila nad5 NC_036103 Group I intron Unpublished
13 Hau.cox3P640a cox3-i2 Hypomyces aurantius cox3 NC_030206 1st one in twintron Deng et al. 2016
14 Hau.cox3P640b cox3-i2 Hypomyces aurantius cox3 NC_030206 2nd one in twintron Deng et al. 2016
15 Hth.cobP429–1 cob-i2 Hirsutella thompsonii cob NC_040165 Strain: ARSEF 9457 Wang et al. 2018
16 Hth.cobP429–2 cob-i2 Hirsutella thompsonii cob MH367296 Strain: ARSEF 1947 Wang et al. 2018
17 Zsa.nad5P717 ND5–717 Zoanthus sansibaricus nad5 KY888672 Coral: Group I intron Chi and Johansen 2017
18 Zsa.cox1P867 COI-867 Zoanthus sansibaricus cox1 KY888672 Coral: Group I intron Chi and Johansen 2017
19 Mbr.nad5P717 Monosiga brevicollis nad5 AF538053 Protist: Group I intron Burger et al. 2003
20 Ddi.cox2P357 Dictyostelium discoideum cox1/2 NC_000895 Protist: Group I intron Ogawa et al. 2000
21 Mpo.nad5P717 Marchantia polymorpha nad5 M68929 Plant: Group I intron Oda et al. 1992
22 Ath.cox2S691 Arabidopsis thaliana cox2 NC_037304 Plant: Group II intron Sloan et al. 2018
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a Examples from lines 1 to 16 are fungal species, and those from lines 17 to 22 are plant/protist/animal species as indicated in the column “Note”

The suggested nomenclature is flexible to fit some special conditions. Firstly, although we suggest three-letter abbreviation of host scientific name, four-or-more-letter abbreviation may be used in cases where the three-letter abbreviation cannot discriminate among all species under investigation. An example is introns at position 717 in nad5 in Candida pseudojiufengensis (Cpse.nad5U717) and Candida psychrophila (Cpsy.nad5P717) (Table 2, lines 11–12). Secondly, twintrons (twin introns) have been described from some fungal mitogenomes with various combinations of group I or II introns nested inside each other or situated next to each other (Hafez and Hausner 2015; Deng et al. 2016). The internal/external or upstream/downstream members of a twintron could be named alphabetically. An example is the side-by-side twintron in cox3 in Hypomyces aurantius, where two group IA introns are arranged in tandem (Deng et al. 2016). The upstream intron of the twintron can be named as Hau.cox3P640a and the downstream one as Hau.cox3P640b (Table 2, lines 13–14). Finally, although introns present at an identical insertion site among different strains of a particular species are generally conserved, distantly related introns are sometimes detected among different strains. Introns of this kind can be named numerically. For example, Hth.cobP429 in different strains of Hirsutella thompsonii showed length variations (e.g., 2.7 kb in ARSEF 9457 and 4.8 kb in ARSEF 1947) (Wang et al. 2018), and the two variants may be named as Hth.cobP429–1 in ARSEF 9457 and Hth.cobP429–2 in ARSEF 1947 (Table 2, lines 15–16).

The suggested nomenclature has been successfully applied to name introns in 16 fungi from different phyla, including both basal and higher fungal lineages (Table 3). These fungi contain introns in all protein-coding genes except atp8, nad2, and nad6, and cob and cox1 are most frequently invaded by introns. These introns are mostly group I introns, but we also find few group II introns as well as few introns with undetermined types. There are a total of 149 introns at 74 insertion sites in these fungi. Using the suggested nomenclature, intron positions in a particular gene can be directly observed and compared across different species. We find some points frequently inserted by introns in different species (e.g., cobP490, cox1P386, cox1P720, cox1P1107). From the intron insertion site numbers, one can also easily understand the phase of an intron, which is phase 0 when an intron inserts between two codons (e.g., cobP393), and phase 1 or 2 when an intron inserts within a codon (e.g., cox1S205, cox1P386). These introns are often found at highly conserved regions (Additional file 2).

Table 3.

Intron positions in mitochondrial protein-coding genes of selected fungal species a

Fungal taxa atp6 atp8 atp9 cob cox1 cox2 cox3 nad1 nad2 nad3 nad4 nad4L nad5 nad6 rps3 No. introns No. genes
with
introns
Cryptomycota
Rozella allomycis 0 -- b 0 0 P731 0 0 1 1
Mucoromycota
Rhizopus oryzae 0 0 P157 P393, P490 P386, P615, P720 P685 P219 0 0 P124 0 0 0 0 9 6
Zoopagomycota
Conidiobolus heterosporus U374 0 P69 P201, P393, P429, P506, P600, P759, P823 P212, P281, P386, P461, P550, P615, P720, P731, P807, P867, P1107, P1125, P1305 P228, P328 P447 U166, P636 0 0 P915 0 P426, U1059 0 0 30 9
Blastocladiomycota
Allomyces macrogynus 0 0 0 P201, P417, P429, P490, P600, P759 P221, P281, S313, P372, P386, P615, P678, P867, P1030, P1107, P1230, P1296 P685 0 P166, P636 0 0 0 0 P426, P717, P934 0 0 24 5
Chytridiomycota
Hyaloraphidium curvatum 0 0 0 P411 0 0 0 0 0 0 0 0 0 0 1 1
Ascomycota
Candida albicans 0 0 0 U393, U429 P386, P709, P720, P1107 0 0 0 0 0 0 0 0 0 6 2
Grosmannia piceiperda NA c NA NA NA NA NA NA NA NA NA NA NA NA NA P159 1 1
Isaria cicadae U572 0 P181 P393, P490, P506, P823 P212, P281, P709, P720, P731, P1057, P1281 P228, P357, P651 P219, P631 P636 0 0 0 0 P417, P570 0 0 21 8
Neurospora crassa P344 0 0 P393, P490 0 0 0 P636 0 P90 P505 P263 P324, P717 0 0 9 7
Saccharomyces cerevisiae 0 0 0 S415, P429, P506, P759, P809 S169, S205, P240, P720, P971, P1107, S1132 0 0 0 12 2
Schizosaccharomyces pombe 0 0 0 S687 P386, P731 0 0 3 2
Tolypocladium inflatum 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0
Basidiomycota
Cryptococcus neoformans 0 0 0 P490 0 0 0 P166 0 0 0 0 0 0 0 2 2
Puccinia striiformis 0 0 0 U429, P809 P386, U615, P709, P720, P807, U1107 P314 0 0 0 0 S495 0 P417, P717 0 0 12 5
Tilletia indica 0 0 0 P490 P212, P386, P709, P1107, P1305 0 0 0 0 0 0 0 P417, P717 0 8 3
Tricholoma matsutake 0 0 0 P823 U281, P372, P386, P720, P900 P318, P357 0 P276 0 0 0 0 P417 0 0 10 5
No. introns 3 0 3 35 65 10 4 8 0 2 3 1 14 0 1 149
No. intron-containing species 3 0 3 13 11 6 3 6 0 2 3 1 7 0 1
No. intron insertion points 3 0 3 13 29 7 3 3 0 2 3 0 7 0 1 74
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a Re-annotation was performed if online or published annotations failed to correctly identify introns. Intron types were determined by RNAweasel (http://megasun.bch.umontreal.ca/RNAweasel)

b “--” indicates the absence of corresponding genes in a particular mitogenome

c NA, not available

In addition to fungi, plants and protists (but rarely in animals) also contain group I or II introns in their mitochondrial genes (Oda et al. 1992; Ogawa et al. 2000; Burger et al. 2003; Chi and Johansen 2017). The nomenclature suggested in this study could potentially apply to plant/protist/animal mitochondrial introns (Table 2, lines 17–22; Additional file 2). Plant mitogenomes, however, are also known to encode several intron-containing protein genes (e.g., nad7, ccmC, rps10, rpl2) that are absent in fungal mitogenomes (Zhang et al. 2011; Sloan et al. 2018). Introns are even found in tRNA-coding genes in plant mitogenomes (Smith et al. 2011). An additional plant reference is necessary to name introns unique to plant mitogenomes.

CONCLUSIONS

A standard nomenclature was suggested for introns in protein-coding genes in fungal mitogenomes. It was proved feasible by naming introns present in mitogenomes of 16 fungi from a broad range of taxonomic classification, and it also had the potential to name introns in plant/protist/animal mitogenomes. Future studies should follow the proposed nomenclature to ensure direct comparison across different studies.

Additional files

Additional file 1: (21.2KB, docx)

Sequences of protein-coding genes of Tolypocladium inflatum ARSEF 3280 (accession number NC_036382). Insertion site of group I introns are shown in red, group II introns in green, and introns with undetermined intron types in shade. (DOCX 21 kb)

Additional file 2: (2.2MB, pptx)

Intron insertion sites for 22 common introns. Exon sequences of cob, cox1, cox2, nad1, and nad5 of different fungal taxa plus few non-fungal taxa were aligned by MAFFT, and visualization of the aligned sequences was performed using ESPript 3.0 (Robert and Gouet 2014) under default settings. Refer to Tables 1 and 2 for organisms represented by accession numbers, and the accession numbers of non-fungal taxa are marked in red boxes. Insertion sites of introns are shown using upward arrows. For phase 0 introns, conserved amino acids before and after insertion sites are listed. The amino acid glycine (G) is frequently seen before insertion sites of phase 0 introns. For phase 1 or 2 introns, conserved amino acids at insertion sites are given, and corresponding triplet codons are marked by a horizontal line. (PPTX 2235 kb)

Acknowledgements

Authors are thankful to the editor and two anonymous reviewers for their suggestions that helped us improve the manuscript.

Adherence to national and international regulations

Not applicable.

Authors’ contributions

YJZ designed the research and wrote the manuscript. SZ performed the research. Both authors read and approved the final manuscript.

Funding

This study was funded by the National Natural Science Foundation of China (31872162), the Research Project Supported by Shanxi Scholarship Council of China (2017–015), Hundred Talents Program of Shanxi Province, and the Special Fund for Large Scientific Instruments and Equipment in Shanxi Province.

Availability of data and materials

All data used in this study are publicly available.

Ethics approval and consent to participate

Not applicable.

Consent for publication

Not applicable.

Competing interests

The authors declare that they have no competing interests.

Footnotes

Publisher’s Note

Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Change history

3/23/2020

After publication of our article (Zhang and Zhang 2019) we have been notified us that the nad4L sequence should be corrected in Additional��file��1. All sequences in the file should be that of NC_036382 (GenBank accession number), but have been erroneously pasted as the nad4L sequence of NC_001715.

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Associated Data

This section collects any data citations, data availability statements, or supplementary materials included in this article.

Supplementary Materials

Additional file 1: (21.2KB, docx)

Sequences of protein-coding genes of Tolypocladium inflatum ARSEF 3280 (accession number NC_036382). Insertion site of group I introns are shown in red, group II introns in green, and introns with undetermined intron types in shade. (DOCX 21 kb)

Additional file 2: (2.2MB, pptx)

Intron insertion sites for 22 common introns. Exon sequences of cob, cox1, cox2, nad1, and nad5 of different fungal taxa plus few non-fungal taxa were aligned by MAFFT, and visualization of the aligned sequences was performed using ESPript 3.0 (Robert and Gouet 2014) under default settings. Refer to Tables 1 and 2 for organisms represented by accession numbers, and the accession numbers of non-fungal taxa are marked in red boxes. Insertion sites of introns are shown using upward arrows. For phase 0 introns, conserved amino acids before and after insertion sites are listed. The amino acid glycine (G) is frequently seen before insertion sites of phase 0 introns. For phase 1 or 2 introns, conserved amino acids at insertion sites are given, and corresponding triplet codons are marked by a horizontal line. (PPTX 2235 kb)

Data Availability Statement

All data used in this study are publicly available.

Articles from IMA Fungus are provided here courtesy of The International Mycological Association

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