Rat PRDM9 shapes recombination landscapes, duration of meiosis, gametogenesis, and age of fertility.
Fertility
Meiotic recombination
PRDM9
Rattus norvegicus
Journal
BMC biology
ISSN: 1741-7007
Titre abrégé: BMC Biol
Pays: England
ID NLM: 101190720
Informations de publication
Date de publication:
28 04 2021
28 04 2021
Historique:
received:
10
09
2020
accepted:
01
04
2021
entrez:
29
4
2021
pubmed:
30
4
2021
medline:
15
12
2021
Statut:
epublish
Résumé
Vertebrate meiotic recombination events are concentrated in regions (hotspots) that display open chromatin marks, such as trimethylation of lysines 4 and 36 of histone 3 (H3K4me3 and H3K36me3). Mouse and human PRDM9 proteins catalyze H3K4me3 and H3K36me3 and determine hotspot positions, whereas other vertebrates lacking PRDM9 recombine in regions with chromatin already opened for another function, such as gene promoters. While these other vertebrate species lacking PRDM9 remain fertile, inactivation of the mouse Prdm9 gene, which shifts the hotspots to the functional regions (including promoters), typically causes gross fertility reduction; and the reasons for these species differences are not clear. We introduced Prdm9 deletions into the Rattus norvegicus genome and generated the first rat genome-wide maps of recombination-initiating double-strand break hotspots. Rat strains carrying the same wild-type Prdm9 allele shared 88% hotspots but strains with different Prdm9 alleles only 3%. After Prdm9 deletion, rat hotspots relocated to functional regions, about 40% to positions corresponding to Prdm9-independent mouse hotspots, including promoters. Despite the hotspot relocation and decreased fertility, Prdm9-deficient rats of the SHR/OlaIpcv strain produced healthy offspring. The percentage of normal pachytene spermatocytes in SHR-Prdm9 mutants was almost double than in the PWD male mouse oligospermic sterile mutants. We previously found a correlation between the crossover rate and sperm presence in mouse Prdm9 mutants. The crossover rate of SHR is more similar to sperm-carrying mutant mice, but it did not fully explain the fertility of the SHR mutants. Besides mild meiotic arrests at rat tubular stages IV (mid-pachytene) and XIV (metaphase), we also detected postmeiotic apoptosis of round spermatids. We found delayed meiosis and age-dependent fertility in both sexes of the SHR mutants. We hypothesize that the relative increased fertility of rat versus mouse Prdm9 mutants could be ascribed to extended duration of meiotic prophase I. While rat PRDM9 shapes meiotic recombination landscapes, it is unnecessary for recombination. We suggest that PRDM9 has additional roles in spermatogenesis and speciation-spermatid development and reproductive age-that may help to explain male-specific hybrid sterility.
Sections du résumé
BACKGROUND
Vertebrate meiotic recombination events are concentrated in regions (hotspots) that display open chromatin marks, such as trimethylation of lysines 4 and 36 of histone 3 (H3K4me3 and H3K36me3). Mouse and human PRDM9 proteins catalyze H3K4me3 and H3K36me3 and determine hotspot positions, whereas other vertebrates lacking PRDM9 recombine in regions with chromatin already opened for another function, such as gene promoters. While these other vertebrate species lacking PRDM9 remain fertile, inactivation of the mouse Prdm9 gene, which shifts the hotspots to the functional regions (including promoters), typically causes gross fertility reduction; and the reasons for these species differences are not clear.
RESULTS
We introduced Prdm9 deletions into the Rattus norvegicus genome and generated the first rat genome-wide maps of recombination-initiating double-strand break hotspots. Rat strains carrying the same wild-type Prdm9 allele shared 88% hotspots but strains with different Prdm9 alleles only 3%. After Prdm9 deletion, rat hotspots relocated to functional regions, about 40% to positions corresponding to Prdm9-independent mouse hotspots, including promoters. Despite the hotspot relocation and decreased fertility, Prdm9-deficient rats of the SHR/OlaIpcv strain produced healthy offspring. The percentage of normal pachytene spermatocytes in SHR-Prdm9 mutants was almost double than in the PWD male mouse oligospermic sterile mutants. We previously found a correlation between the crossover rate and sperm presence in mouse Prdm9 mutants. The crossover rate of SHR is more similar to sperm-carrying mutant mice, but it did not fully explain the fertility of the SHR mutants. Besides mild meiotic arrests at rat tubular stages IV (mid-pachytene) and XIV (metaphase), we also detected postmeiotic apoptosis of round spermatids. We found delayed meiosis and age-dependent fertility in both sexes of the SHR mutants.
CONCLUSIONS
We hypothesize that the relative increased fertility of rat versus mouse Prdm9 mutants could be ascribed to extended duration of meiotic prophase I. While rat PRDM9 shapes meiotic recombination landscapes, it is unnecessary for recombination. We suggest that PRDM9 has additional roles in spermatogenesis and speciation-spermatid development and reproductive age-that may help to explain male-specific hybrid sterility.
Identifiants
pubmed: 33910563
doi: 10.1186/s12915-021-01017-0
pii: 10.1186/s12915-021-01017-0
pmc: PMC8082845
doi:
Substances chimiques
Chromatin
0
Histone-Lysine N-Methyltransferase
EC 2.1.1.43
prdm9 protein, mouse
EC 2.1.1.43
Types de publication
Journal Article
Research Support, N.I.H., Extramural
Research Support, Non-U.S. Gov't
Langues
eng
Sous-ensembles de citation
IM
Pagination
86Subventions
Organisme : Grantová Agentura České Republiky
ID : 14-20728S
Organisme : Grantová Agentura České Republiky
ID : 16-06548S
Organisme : Grantová Agentura České Republiky
ID : 19-06272S
Organisme : Akademie Věd České Republiky
ID : RVO 68378050
Organisme : Ministerstvo Školství, Mládeže a Tělovýchovy
ID : LM2018126
Organisme : Ministerstvo Školství, Mládeže a Tělovýchovy
ID : CZ.02.1.01/0.0/0.0/18_046/0015861
Organisme : Myotonic Dystrophy Foundation
ID : 1-FY13-506
Organisme : Foundation for the National Institutes of Health
ID : 1R01GM084104
Organisme : Ministry of Education, Youth and Sports of the Czech Republic
ID : LQ1604
Organisme : Ministry of Education, Youth and Sports of the Czech Republic
ID : LM2015040
Organisme : Ministry of Education, Youth and Sports of the Czech Republic
ID : LM2018126
Organisme : Ministry of Education, Youth and Sports of the Czech Republic
ID : LM2015042
Organisme : Ministry of Education, Youth and Sports of the Czech Republic
ID : LM2015085
Organisme : Ministry of Education, Youth and Sports of the Czech Republic
ID : LM2015062
Organisme : European Regional Development Fund
ID : CZ.1.05/1.1.00/02.0109 BIOCEV
Organisme : European Regional Development Fund
ID : CZ.1.05/2.1.00/19.0395
Organisme : European Regional Development Fund
ID : CZ.02.1.01/0.0/0.0/16_013/0001775
Organisme : European Regional Development Fund
ID : CZ.02.1.01/0.0/0.0/18_046/0015861
Références
Nat Protoc. 2009;4(8):1184-91
pubmed: 19617889
Chromosoma. 2020 Mar;129(1):69-82
pubmed: 31940063
Dev Biol. 2003 Jun 15;258(2):334-48
pubmed: 12798292
Chromosoma. 2015 Sep;124(3):397-415
pubmed: 25894966
EMBO J. 2009 Sep 2;28(17):2616-24
pubmed: 19644444
Science. 2014 Nov 14;346(6211):1256442
pubmed: 25395542
Reproduction. 2020 Jul;160(1):53-64
pubmed: 32272448
Science. 2010 Feb 12;327(5967):835
pubmed: 20044538
Genome Res. 2017 Apr;27(4):580-590
pubmed: 28336543
Genome Res. 2019 Jul;29(7):1078-1086
pubmed: 31186301
Genes Dev. 2016 Feb 1;30(3):266-80
pubmed: 26833728
PLoS Genet. 2014 Feb 06;10(2):e1004088
pubmed: 24516397
Brief Bioinform. 2013 Mar;14(2):144-61
pubmed: 22908213
Nature. 2012 May 13;485(7400):642-5
pubmed: 22660327
PLoS Genet. 2016 Jun 30;12(6):e1006146
pubmed: 27362481
Dev Biol. 2014 Aug 1;392(1):108-16
pubmed: 24797635
Nature. 2016 Feb 11;530(7589):171-176
pubmed: 26840484
Sci Rep. 2016 Aug 02;6:30912
pubmed: 27480068
Genome Biol. 2011 Sep 14;12(9):R86
pubmed: 21917142
Science. 2015 Nov 20;350(6263):928-32
pubmed: 26586757
Science. 2010 Feb 12;327(5967):876-9
pubmed: 20044541
Science. 2015 Nov 20;350(6263):932-7
pubmed: 26586758
Genome Res. 2012 Jan;22(1):51-63
pubmed: 22006216
Mamm Genome. 2012 Jun;23(5-6):346-55
pubmed: 22258617
Orphanet J Rare Dis. 2006 Apr 06;1:9
pubmed: 16722528
Exp Cell Res. 1961 Sep;24:495-507
pubmed: 13871511
Folia Biol (Praha). 2017;63(1):27-30
pubmed: 28374672
PLoS Genet. 2015 Jan 08;11(1):e1004916
pubmed: 25568937
Proc Natl Acad Sci U S A. 1997 Jul 22;94(15):8058-63
pubmed: 9223314
Elife. 2018 Mar 14;7:
pubmed: 29537370
Sci Rep. 2017 Dec 4;7(1):16878
pubmed: 29203879
Science. 2016 Apr 22;352(6284):474-7
pubmed: 26940866
Mutat Res. 1996 Jun 10;352(1-2):169-72
pubmed: 8676906
J Biol Chem. 2014 Apr 25;289(17):12177-12188
pubmed: 24634223
PLoS One. 2011;6(11):e25498
pubmed: 22102853
PLoS Genet. 2012;8(11):e1003044
pubmed: 23133405
Nat Protoc. 2014 Apr;9(4):773-93
pubmed: 24625778
Elife. 2014 Dec 09;3:
pubmed: 25487987
Genetics. 2011 Mar;187(3):643-57
pubmed: 21149647
Physiol Rev. 1972 Jan;52(1):198-236
pubmed: 4621362
Proc Natl Acad Sci U S A. 2006 Sep 5;103(36):13415-20
pubmed: 16938833
PLoS One. 2014 Apr 22;9(4):e95806
pubmed: 24756080
Ann N Y Acad Sci. 1952 Nov 20;55(4):548-73
pubmed: 13139144
Nature. 2011 Apr 21;472(7343):375-8
pubmed: 21460839
Genome Res. 2012 May;22(5):957-65
pubmed: 22367190
Methods Enzymol. 2018;601:391-418
pubmed: 29523240
Dev Cell. 2002 Jun;2(6):819-30
pubmed: 12062093
Genome Biol Evol. 2014 Dec 19;7(2):522-30
pubmed: 25527838
J Anat. 2009 Oct;215(4):462-71
pubmed: 19627387
Epigenetics Chromatin. 2015 Sep 07;8:31
pubmed: 26351520
Physiol Res. 2014;63(Suppl 1):S1-8
pubmed: 24564651
Elife. 2017 Jun 06;6:
pubmed: 28590247
Genetics. 2020 Oct;216(2):585-597
pubmed: 32817010
PLoS Genet. 2015 Sep 14;11(9):e1005512
pubmed: 26368021
Science. 2010 Feb 12;327(5967):836-40
pubmed: 20044539
PLoS Genet. 2013;9(12):e1003984
pubmed: 24348265
Genetics. 2010 Sep;186(1):339-51
pubmed: 20610405
Nature. 2005 Nov 17;438(7066):374-8
pubmed: 16292313
Genetics. 1999 Apr;151(4):1569-79
pubmed: 10101178
Nature. 2004 Apr 1;428(6982):493-521
pubmed: 15057822
Reprod Biol Endocrinol. 2010 Jan 10;8:3
pubmed: 20064221
Int Rev Cell Mol Biol. 2012;298:179-227
pubmed: 22878107
Proc Natl Acad Sci U S A. 2013 Feb 5;110(6):E468-77
pubmed: 23329330
PLoS Genet. 2016 Apr 22;12(4):e1005906
pubmed: 27104744
Curr Hypertens Rep. 2010 Feb;12(1):5-9
pubmed: 20425152
PLoS One. 2014 Dec 26;9(12):e115669
pubmed: 25541964
Genome Res. 2010 Jun;20(6):791-803
pubmed: 20430781
Mol Cell. 2018 Mar 1;69(5):853-865.e6
pubmed: 29478809
Genes Dev. 2012 May 1;26(9):958-73
pubmed: 22549958
Science. 2009 Jan 16;323(5912):373-5
pubmed: 19074312
Cell Rep. 2013 Oct 17;5(1):13-20
pubmed: 24095733
Cytogenet Genome Res. 2015;147(2-3):81-94
pubmed: 26730606
Reprod Biol Endocrinol. 2012 Sep 11;10:79
pubmed: 22967030