PRDM9: meiosis and recombination
Introduction
PRDM9 is a very peculiar gene on human chromosome 5 whose role -- after many false starts -- is only now becoming clear: scanning the genome with its 13 zinc fingers to mark recombination hotspots by its histone methylase where its transcription factor domain can direct additional proteins to initiate meiosis. Recombination between homologous chromosomes is essential to their proper alignment and separation into daughter cells.
Such a critical protein would normally be exceedingly conserved. However this is not the case at all. It proves exceedingly difficult to find a comprehensive set of PRDM9 orthologs in sequenced mammalian genomes, with immense confusion in the literature with other composite domain proteins with some overlap in domain content but no real homology.
Comparative genomics of PRDM9 and PRDM7
PRDM9 is one of many human proteins sharing a set of common domains, as well as various multiplicities of the zinc finger domain C2H2. The diagram at left shows an effort at organizing these into phylogenetic tree according to structural considerations of the SET domain these proteins all share.
The traditional SET domain is too small for an enzyme with distinctive substrates so flanking sequence must be added despite its lack of apparent conservation. Using S-adenosyl methionine, PRDM9 places the third methyl group only on the fourth position arginine in histone H3, one of many such epigenetic methylases in the human genome. The histone recognized by such methylases correlates poorly with evolutionary grouping by SET domain (figure).
The upper left corner shows the variability in domain structure. While PRDM9 and PRDM7 share the same domains (an upstream KRAB domain is not shown), of PR-class homologs, PRDM11 shares only the SET domain despite nesting deep within the PRDM9 subtree. PRDM4 has both the SET and C2H2 domains, possibly sharing the early C2H2 domain in an exon beginning with a phase 2 splice acceptor (as shown in reference sequence section). Overall however, PRDM9 and PRDM7 have no full length homologs with matching exon structure. Even the SET domain is intronated differently within PR-class proteins (with the sole exception of PRDM11), suggesting either ancient divergence or unusual evolution. These incongruities may have arisen from domain shuffling, gain and loss.
The human PRDM9 sequence below is annotated in color for domains relative to exon breaks. The protein can be best understood in terms of concatenated domains, not all of which may be present in antecedent and descendant homologs. The first two domains KRAB and SSXRD interact with transcription factors.
Each C2H2 domain -- so named for two cysteines and two histidines liganding to a structural zinc ion -- recognizes a specific trinucleotide (more or less) and so concatenated in a large array recognize specific binding sites along the genome, though tolerance of nucleotide variability and synergistic effects between adjacent units make it difficult to read out these sites precisely, despite immense efforts.
The concatenated C2H2 domains, conserved at the amino acid level so necessarily similar at the dna level, are prone to replication slippage. This process can give rise to point mutations as well as leading to a peaked distribution of repeat number rather than to a single number. Many other unrelated genes with internal repeats (such as the octapeptide region of the prion gene PRNP) are also affected by replication slippage. Such proteins regions are conveniently identified genomewide by mRNA dot plots.
The C2H2 domains generally reside in a long distinctive terminal exon of splicing phase 2 that has been shuffled over mammalian evolutionary time into various contexts. Concepts such as paralogy and orthology need piecewise definitions in these composite proteins. Synteny (gene adjacency) plays a major role in reliably deconstructing events in specific lineages.
Here the unrelated single-copy conserved gene GAS8 plays an important role. PRDM7 occurs immediately distal to it on the negative strand, making the two genes are convergently transcribed). PRDM7 is otherwise the last gene on the q arm of its chromosome in many species which may predispose it to copy number dispersal events. PRDM9 is not consistently located within placental mammals, suggesting independent relocation events.
Both PRDM9 and PRDM7 contain a seldom-mentioned C2H2 domain early in the exon annotated by SwissProt and readily found by the online domain tools regardless of species. This domain conserves the four critical residues needed for zinc binding (and so the associated fold) but lacks the terminal cap TGEKP which otherwise serves to lock down a C2H2 zinc finger after it has scanned along genomic dna to an appropriate trinucleotide. The function of this early domain and the following 112 residues are unknown -- no homologous 3D structure has ever been determined.
The first C2H2 of the main repeat region is proximaly degenerate, beginning in VKY in all species (instead of YCE). The tyrosine cannot plausibly replace the usual cysteine for zinc binding though the other three needed residues are present. This domain ends in a typical cap region TGEKP. Humans are the exception here where the conserved helix-ending proline has been replaced with leucine in the reference human genome with unknown functional consequences.
>PRDM9_homSap Homo sapiens (human) Q9NQV7 10 exons chr5:23,509,579 span 18,301 bp KRAB SSXRD SET C2H2 cap 0 MSPEKSQEESPEEDTERTERKPM 0 0 VKDAFKDISIYFTKEEWAEMGDWEKTRYRNVKRNYNALITI 1 2 GLRATRPAFMCHRRQAIKLQVDDTEDSDEEWTPRQQ 1 2 VKPPWMALRVEQRKHQK 0 0 GMPKASFSNESSLKELSRTANLLNASGSEQAQKPVSPSGEASTSGQHSRLKL 1 2 ELRKKETERKMYSLRERKGHAYKEVSEPQDDDYL 1 2 YCEMCQNFFIDSCAAHGPPTFVKDSAVDKGHPNRSALSLPPGLRIGPSGIPQAGLGVWNEASDLPLGLHFGPYEGRITEDEEAANNGYSWL 0 0 ITKGRNCYEYVDGKDKSWANWMR 2 1 YVNCARDDEEQNLVAFQYHRQIFYRTCRVIRPGCELLVWYGDEYGQELGIKWGSKWKKELMAGR 1 2 EPKPEIHPCPSCCLAFSSQKFLSQHVERNHSSQNFPGPSARKLLQPENPCPGDQNQEQQYPDPHSRNDKTKGQEIKERSKLLNKRTWQREISRAFSSPPKGQMGSCRVGKRIMEEESRTGQKVNPGNTGKLFVGVGISRIAK VKYGECGQGFSVKSDVITHQRTHTGEKL YVCRECGRGFSWKSHLLIHQRIHTGEKP YVCRECGRGFSWQSVLLTHQRTHTGEKP YVCRECGRGFSRQSVLLTHQRRHTGEKP YVCRECGRGFSRQSVLLTHQRRHTGEKP YVCRECGRGFSWQSVLLTHQRTHTGEKP YVCRECGRGFSWQSVLLTHQRTHTGEKP YVCRECGRGFSNKSHLLRHQRTHTGEKP YVCRECGRGFRDKSHLLRHQRTHTGEKP YVCRECGRGFRDKSNLLSHQRTHTGEKP YVCRECGRGFSNKSHLLRHQRTHTGEKP YVCRECGRGFRNKSHLLRHQRTHTGEKP YVCRECGRGFSDRSSLCYHQRTHTGEKP YVCREDE* 0 -1 23 6 traditional numbering of dna recognizing amino acids HPCPSCCLAFSSQKFLSQHVERNH alignment of early C2H2 domain * * * * zinc liganding positions
Only in PRDM11 (and PRDM1 to a lesser extent) is the SET domain intronated like PRDM9 and PRDM7: >PRDM9_homSap 2 YCEMCQNFFIDSCAAHGPPTFVKDSAVDKGHPNRSALSLPPGLRIGPSGIPQAGLGVWNEASDLPLGLHFGPYEGRITEDEEAANNGYSWL 0 0 ITKGRNCYEYVDGKDKSWANWMR 2 1 YVNCARDDEEQNLVAFQYHRQIFYRTCRVIRPGCELLVWYGDEYGQELGIKWGSKWKKELMAGR 1 >PRDM11_homSap intronation of SET domain 2 FCESCQEYFVDECPNHGPPVFVSDTPVPVGIPDRAALTIPQGMEVVKDTSGESDVRCVNEVIPKGHIFGPYEGQISTQDKSAGFFSWL 0 0 IVDKNNRYKSIDGSDETKANWMR 2 1 YVVISREEREQNLLAFQHSERIYFRACRDIRPGEWLRVWYSEDYMKRLHSMSQETIHRNLAR 1 >PRDM1_homSap intronation of SET domain 0 AAPKCNSSTVRFQGLAEGTKGTMKMDMEDADMTLWTEAEFEEKCTYIVNDHPWDSGADGGTSVQAEASLPRNLLFKYATNSEE 0 0 VIGVMSKEYIPKGTRFGPLIGEIYTNDTVPKNANRKYFWR 0 0 IYSRGELHHFIDGFNEEKSNWMRYVNPAHSPREQNLAACQNGMNIYFYTIKPIPANQELLVWYCRDFAERLHYPYPGELTMMNL 1 >PRDM4_homSap intronation of SET domain 2 WCTLCDRAYPSDCPEHGPVTFVPDTPIESRARLSLPKQLVLRQSIVGAEV 1 2 GVWTGETIPVRTCFGPLIGQQSHSMEVAEWTDKAVNHIWK 0 0 IYHNGVLEFCIITTDENECNWMMFVRKAR 2 1 NREEQNLVAYPHDGKIFFCTSQDIPPENELLFYYSRDYAQQI 1
Divergence of SET domains:
Different segmental duplications relate PRDM9 and PRDM7
In humans, PRDM9 and PRDM7 are related by a 26 kbp segmental duplication that begins about 8 kbp upstream of the start codon and continues through most of the 3' UTR. Since the retroposon patterns are nearly identical, the duplication must be fairly recent. The overall percent identity of non-coding dna is about 93%, again inconsistent with either early (within stem placental or late divergence (post-chimpanzee). The duplication contains a potentially diagnostic 1845 bp retroposon-free region upstream of the first coding exon.
Note PRDM7 is situated at the extreme tip of chromosome 16q, perhaps predisposing it to chromosomal copy number rearrangements. The syntenic context is TUBB3+ DEFB+ AFG3L1+ DBNDD1- GAS8+ PRDM7- qTel, meaning it is transcribed convergently with GAS8, a non-homologous highly conserved single copy gene often detectable even in low coverage genomes in the small contig containing PRDM7. This association has been extremely stable over boreoeutheran placental mammal evolutionary time and so serves to reliably define PRDM7 orthologs and their spin-off copies. Elephants also have a gene pair similar to human PRDM9 and PRDM7. The former is at a syntenically novel site but the latter is an old pseudogene but still detectably adjacent to GAS8 in opposite orientation. It thus follows that 'PRDM9' in elephant is an independent earlier spin-off of its conventional PRDM7 gene. This is consistent with telomeric susceptibility to repeated rearrangements.
Recall here the actual definition of gene orthology: two genes in two species are orthologous if they are vertically descended from the same gene in their last common ancestor. Here the LCA of human and elephant is ur-placental mammal which had PRDM7 but no PRDM9. The two PRDM9 genes are thus not descended from a common ancestral PRDM9 gene but from parallel gene duplications of a common PRDM7 gene at different times in different clades during the course of mammalian speciation. Such genes are called in-paralogs within a given species and co-orthologs across them.
The syntenic context of PRDM9 is quite variable, supporting the scenario of multiple origins. This context can be used to count the number of distinct segmental duplications of PRDM7. For example, in humans, PRDM9 basically lies in a retroposon-rich gene desert but is eventually flanked by two pairs of cadherin genes at the much larger scale of 7 mbp. In rhesus, these same genes are seen (with some minor rearrangements), establishing that this PRDM9 segmental duplication preceded the divergence of old world monkeys.
Marmoset has a seemingly functional PRDM7 in the usual position facing GAS8, still at the extreme end of chromosome 20. The cadherin cluster is intact on chr2:178,954,165-180,696,523. However Blastx of the intervening dna -- which is similar in size to rhesus and human so not suggesting large deletions -- shows not even a suggestion of an old PRDM9 pseudogene. The assembly is gapless here. and Blastx is sensitive enough to detect very old pseudogenes provided they decayed by small indels and nucleotide substitutions. Thus it appears that PRDM7 never duplicated in marmoset -- placing that even in the stem to old world monkeys (or prior to tarsier divergence -- that assembly has poor coverage). Note that the marmoset PRDM7 has a respectable terminal zinc finger array of twelve units, enough to specify 36 bp.
Gene Strand Protein Start Species CDH18 - cadherin 18 19981287 homSap ponAbe macMul CDH12 - cadherin 12 22853731 homSap ponAbe macMul calJac PRDM9 + human PRDM9 23528704 homSap ponAbe macMul calJac CDH10 - cadherin 10 24644911 homSap ponAbe macMul calJac CDH9 - cadherin 9 27038689 homSap ponAbe macMul
Lemurs present a new complication. The Otolemur assembly has two distinct and seemingly functional PRDM7 copies (each with seven zinc fingers) containing GAS8 end-sequence in expected opposite orientation. One of the GAS8 copies appears to be a pseudogene. This represents a new type of lineage-specific segmental duplication. There is no sign of PRDM9. The other lemur with an assembly, Microcebus murinus, has but a single copy, again with seven zinc fingers. The only relevant contigs (ABDC01433247 and ABDC01371462) contain no coding syntenic information so this gene cannot be assigned to PRDM7 with certainty.
The tree shrew assembly, like tarsier, has low coverage and only blast matches to zinc finger arrays that cannot be assigned to the PRDM family. This cannot be totally attributed to low coverage because many ordinary genes are satisfactorily represented in these species. Other issues such as telomeric position, gene copy number (mobility), pseudogenization, deletional loss, chimerization, and individual heterozygosity must be affecting recovery of PRDM9 gene models in these species.
Moving on to laurasiatheres, Bos taurus presents a much more complicated situation. First, the GAS8 locus on chr18 contains the first two exons of a PRDM7 pseudogene in expected orientation but distal regions of the gene are completely deleted. The cadherin locus on chr20 is also intact but the 2.6 mbp region between CDH12 and CDH10 contains no indication of PRDM9, consistent with that segmental duplication being primate-specific and PRDM7 being the older parental location. This holds in the Baylor 4.0 assembly carried at UCSC, the Baylor 4.2 assembly, and the alternative assembly of the same data, UMD3.1. The latter two can be queried by the genomic [http://www.ncbi.nlm.nih.gov/genome/seq/BlastGen/BlastGen.cgi?taxid=9913 blast server} at NCBI.
A third locus on chr 1 hosts an unreviewed GenBank pipline entry called PRDM9, derived as NW_003053109 from the alternative bovine assembly UMD3.1 Staff corrected an unspecified frameshift to fix the reading frame -- a dangerous practise in a gene family so prone to pseudogenization. The gene, called PRDM9a here, resides on the extreme end of chromosome 1 and differs from the Baylor 4.0 assembly at two amino acids outside the zinc finger region. The syntenic context here is novel: EFHB- RAB5A+ PCAF+ ZNF596- PRDM9a- which corresponds overall to human chr 3. The juxtapositioning of two zinc finger proteins on the same strand causes PRDM9 alignments to extend spuriously into the 12 zinc fingers of ZNF596, jumping over its 5 earlier coding exons.
ZNF596 contains a KRAB domain but no SET methylase. Humans encode a best-blast protein of the same assigned name on chr 8 (77% identity). Note the early exons of ZNF596 can be added to end of PRDM9a to form an artificial probe for this association in other species, though the two genes have a 43,400 bp spacer in cow, which is large relative to contig size in low coverage assemblies. The sole fragmentary transcript from yak testis (EF432551) is nearly identical to this PRDM9a, suggesting that the gene -- and perhaps its syntenic location -- became established prior to yak-cow divergence and is still functional. However its array of seven zinc fingers could recognize at most a region of 21 bp.
ZNF596 did not arise from a PRDM9-like gene through loss of the SET domain, though it is one of the better matches within the large zinc finger family. Excluding the zinc finger domain, ZNF343, ZNF133 and ZNF169 provide much higher blastp scores, as they also do just comparing the zinc finger arrays. The juxtaposition of ZNF596 and PRDM9a is likely coincidental rather than a consequence of inhomogeneous recombination between zinc fingers bringing PRDM9 to this site.
The fourth PRDM9 locus of interest, called here PRDM9b, is still not mapped to any bovine chromosome. It resides in contig DAAA02065087 in the UMD3.1 assembly and is temporarily assigned to chr Un.004.649 at Baylor assembly. Here the reading frame in exon two can be restored if a run of 5 A's is corrected to 6 A's. That is done here in the reference sequences because this is typically just sequencing error. The protein has a full set of domains KRAB SSXRD SET C2H2 with a moderate zinc finger array of five. Synteny cannot be determined in chr Un features which can simply pool unrelated unplaceable contigs into a manageable unit. Flanking dna in DAAA02065087map to several places in the cow genome, suggesting this feature has copy number attributes, perhaps of telomeric repeat type. PRDM9b is not a recent feature because it differs at a considerable number of amino acids from other PRDM9 in the cow genome. These substitutions avoid highly conserved residues, not consistent with early pseudogenization. PRDM9b is capable of histone marking but it is not clear whether that has functional significance to meiosis.
Yet another locus in the Baylor 4.0 assembly, called PRDM9c here, could not initially be placed on a cow chromosome. While such features are often assembly artefacts, this one is supported by a transcript from 4-cell embryos (GO353654) consistent with a role in or after meiosis. In UMD3.1, this gene has been placed on chr X. Despite a very large contig, no zinc fingers occur in any reading frame, suggesting that the gene was transferred here without the last exon (or it subsequently got deleted). In any event, the penultimate exon does not have a phase 1 splice donor in expected position and so terminates at the next stop codon downstream. The protein retains the KRAB, SSXRD and SET domains but does not possess the ability to scan or bind dna. It has accrued various amino acid substitutions relative to other bovine that rule out recent establishment.
Finally, two additional genes, denoted PRDM9d and PRDM9e here, are located as a parallel tandem pair in a higher quality region of bovine chr X. These are 96% identical as proteins, consistent with one being derived fairly recently from the other. Synteny here will not be informative until other ruminant genomes become available.
Overall the situation in cow is very different from primates and rodents. Results there about the function of single-copy autosomal PRDM9 gnes in meiosis markup can scarcely be carried over to a species with five seemingly intact genes, three of which are on chr X (which intriguingly has the very limited pseudoautosomal region on chr Y where it can cross over).
The cow situation cannot be limited to the Hereford breed used for the genome project because the PRDM9 are too diverged from one another outside the zinc finger region. Indeed there is some suggestion from sheep genome that it too has many of these copies. However other cetartiodactyl genomes (dolphin, pig and alpaca) and other laurasiatheres (panda, dog, cat, shrew, bats) do not show these copies, suggesting that this complexity could be limited to pecoran ruminants. All-vs-all blastp percent identities are consistent with this, though rates of evolution in this gene family are hardly typical.This cannot be resolved with cow genome alone -- there is no good candidate still present for parent gene to all these copies. These results are summarized in the table below:
Gene #ZNF Status Chr Synteny cDNA Accession 9a_bosTau 9b_bosTau 9e_bosTau 9a_oviAri 9a_turTru 7_ailMel PRDM7 - pseudo 18 GAS8 no none -- -- -- -- -- -- PRDM9a 7 ok 1 ZNF596 yes NW_003053109 100% 85% 81% 82% 76% 72% PRDM9b 5 ok ? not det no DAAA02065087 81% 100% 78% 79% 72% 68% PRDM9c 0 ok X not det yes XM_002699750 80% 80% 82% 83% 74% 73% PRDM9d 9 ok X --- no none 80% 78% 96% 93% 73% 67% PRDM9e 9 ok X --- no none 81% 78% 100% 93% 73% 68%
Structural considerations in C2H2 zinc fingers
High resolution structures of C2H2 zinc finger domains have been available for decades. As the name suggests, the divalent zinc atom locks the two cysteines and two histidines into a rigid geometry providing a core conformation that a small peptide of 28 residues could not otherwise stably assume. Note in the unbound state, finger tips must retain flexibility while the domain ensemble scans its genome for specific dna sequences appropriate to its function. Each finger binds a trinucleotide -- in effect making a zinc finger the protein counterpart to tRNA anticodon. However overall binding is not a simple read-off code because adjacent fingers alter each other's specificities in subtle ways.
The linker region TGEKP plays a key role when the correct DNA sequence is encountered, snap-locking its finger down onto its target by capping the C-terminus of its alpha helix. A hydrogen bond between the first threonine and middle glutamate is key to this binding-induced conformational shift. From comparative genomics, it appears that a serine in first position can also form this hydrogen bond. The role of the glycine is to stay out of the way; the lysine counterbalances the negative charge of the glutamate; the proline terminates any helical propensity, allowing a fresh start in the adjacent finger.
While this motif is immensely conserved within C2H2 zinc finger of PDRM9 homologs, exceptions do occur. It is important to understand these because these loss of dna lock-down could loosen or even eliminate trinucleotide binding specificity. Such steps might represent initial stages of pseudogenization. However many exceptions occur within the first or last fingers. It is also common for fragmentary and imperfect motifs to end the protein, sometimes continuing on in another reading frame past the current stop codon.
Note in aligning zinc finger motifs, the breaks should always be put at the end of the linker region. It is completely illogical to break at the first cysteine as some authors do because capping by the linker region is specific to its zinc finger, not the following one.
Predicting dna binding sites of zinc finger domains
Online References
Open 37 abstracts on PRDM9 and related issues. Or the reverse chronological list below provides free full text for individual articles when that is available:
abs 2011 Neaves Unisexual reproduction among vertebrates. Trends Genet. 2011 Mar;27(3):81-8. abs 2011 Ponting What are the genomic drivers of the rapid evolution of PRDM9? Trends Genetics (2011) 1–7 htm 2011 Yanover Extensive protein and DNA backbone sampling improves structure-based specificity prediction for C2H2 zinc fingers. Nucleic Acids Res. 2011 Feb 22 pdf 2011 Ubeda Red Queen theory of recombination hotspots. J Evol Biol. 2011 Mar;24(3):541-53. abs 2010 Hochwagen Meiosis: a PRDM9 guide to the hotspots of recombination. Curr Biol. 2010 Mar 23;20(6):R271-4. abs 2010 Klug The discovery of zinc fingers and practical applications in gene regulation and genome manipulation. Q Rev Biophys. 2010 Feb;43(1):1-21. abs 2010 Berg PRDM9 variation strongly influences recombination hot-spot activity and meiotic instability in humans. Nat Genet. 2010 Oct;42(10):859-63. abs 2010 McVean PRDM9 marks the spot. Nat Genet. 2010 Oct;42(10):821-2. pdf 2010 Kong Fine-scale recombination rate differences between sexes, populations and individuals. Nature. 2010 Oct 28;467(7319):1099-103. pmc 2010 Parvanov Prdm9 controls activation of mammalian recombination hotspots. Science. 2010 Feb 12;327(5967):835. pmc 2010 Lorenz The ancient mammalian KRAB zinc finger gene cluster on human chromosome 8q24.3 BMC Genomics. 2010 Mar 26;11:206. pmc 2010 Neale PRDM9 points the zinc finger at meiotic recombination hotspots. Genome Biol. 2010;11(2):104. pmc 2010 Sandovici PRDM9 sticks its zinc fingers into recombination hotspots and between species. F1000 Biol Rep. 2010 May 24;2. pmc 2010 Billings Patterns of recombination activity on mouse chromosome 11 revealed by high resolution mapping. PLoS One. 2010 Dec 8;5(12):e15340. htm 2010 Cheung Genetic control of hotspots. Science. 2010 Feb 12;327(5967):791-2. pdf 2010 Urnov Highly efficient endogenous human gene correction using designed zinc-finger nucleases. Nature. 2005 Jun 2;435(7042):646-51. htm 2010 Zheng Detecting sequence polymorphisms associated with meiotic recombination hotspots in the human genome. Genome Biol. 2010;11(10):R103. htm 2010 Baudat PRDM9 is a major determinant of meiotic recombination hotspots in humans and mice. Science. 2010 Feb 12;327(5967):836-40. htm 2010 Myers Drive against hotspot motifs in primates implicates the PRDM9 gene in meiotic recombination. Science. 2010 Feb 12;327(5967):876-9. pmc 2009 Berglund Hotspots of biased nucleotide substitutions in human genes. PLoS Biol. 2009 Jan 27;7(1):e26. pmc 2009 Thomas Evolution of C2H2-zinc finger genes revisited. BMC Evol Biol. 2009 Mar 4;9:51. pmc 2009 Oliver Accelerated evolution of the Prdm9 speciation gene across diverse metazoan taxa. PLoS Genet. 2009 Dec;5(12):e1000753. pmc 2009 Thomas Extraordinary molecular evolution in the PRDM9 fertility gene. PLoS One. 2009 Dec 30;4(12):e8505. htm 2009 Willis Origin of species in overdrive. Science. 2009 Jan 16;323(5912):350-1. htm 2009 Irie Single-nucleotide polymorphisms of the PRDM9 (MEISETZ) gene in patients with nonobstructive azoospermia. J Androl. 2009 Jul-Aug;30(4):426-31. htm 2009 Mihola A mouse speciation gene encodes a meiotic histone H3 methyltransferase. Science. 2009 Jan 16;323(5912):373-5. abs 2008 Brayer The protein-binding potential of C2H2 zinc finger domains. Cell Biochem Biophys. 2008;51(1):9-19. pmc 2008 Duret The impact of recombination on nucleotide substitutions in the human genome. PLoS Genet. 2008 May 9;4(5):e1000071. pmc 2008 Miyamoto Two single nucleotide polymorphisms in PRDM9 (MEISETZ) gene may be a genetic risk factor for Japanese patients with azoospermia by meiotic arrest. J Assist Reprod Genet. 2008 Nov-Dec;25(11-12):553-7. htm 2008 Cho Prediction of DNA binding sites for zinc finger proteins. BBRC 2008 May 9;369(3):845-8. pmc 2007 Coop Live hot, die young: transmission distortion in recombination hotspots. PLoS Genet. 2007 Mar 9;3(3):e35. pmc 2007 Fumasoni Family expansion and gene rearrangements contributed to the functional specialization of PRDM genes in vertebrates. BMC Evol Biol. 2007 Oct 4;7:187. pdf 2006 Phillips A family of zinc-finger proteins is required for chromosome-specific pairing and synapsis during meiosis. Dev Cell. 2006 Dec;11(6):817-29. htm 2006 Birtle Meisetz and the birth of the KRAB motif. Bioinformatics. 2006 Dec 1;22(23):2841-5. pdf 2006 Hayashi Meisetz, a novel histone tri-methyltransferase, regulates meiosis-specific epigenesis. Cell Cycle. 2006 Mar;5(6):615-20. abs 2000 Laity DNA-induced alpha-helix capping in conserved linker sequences is a determinant of binding affinity in Cys(2)-His(2) zinc fingers. J Mol Biol. 2000 Jan 28;295(4):719-27.
Curated reference sequences
The sequences below have been compiled from genome projects -- only rarely do validating transcripts exist at GenBank. Sequences with a single frameshift or other glitch have been edited to allow full length proteins on the theory that the error either reflects an aberrant atypical individual chosen for sequencing or simple error in low coverage projects within a difficult repeat region. However such sequences may instead reflect early stages of pseudogenization. Many sequences are in fact clearly pseudogenes; here recognizable exons have been collected to allow rough dating of loss of function.
In the case of more intensively studied species such as human and mouse, the number of C2H2 repeats varies widely. Only the most common representative is shown here. This variation likely occurs in all species but the individual animal chosen for sequencing may or may not be typical. Many clades have distinctive patterns of gene amplification and gene loss, making both orthologous and functional comparisons problematic.
Other useful sequences such as the GAS8 synteny neighbor, other zinc finger quasi-homologs having similar exon and domain structures, and bogus orthologs outside of mammals are also included for reference purposes.
>PRDM9_homSap Homo sapiens (human) Q9NQV7 10 exons chr5:23,509,579 size 18,301 bp KRAB SSXRD SET C2H2 0 MSPEKSQEESPEEDTERTERKPM 0 0 VKDAFKDISIYFTKEEWAEMGDWEKTRYRNVKRNYNALITI 1 2 GLRATRPAFMCHRRQAIKLQVDDTEDSDEEWTPRQQ 1 2 VKPPWMALRVEQRKHQK 0 0 GMPKASFSNESSLKELSRTANLLNASGSEQAQKPVSPSGEASTSGQHSRLKL 1 2 ELRKKETERKMYSLRERKGHAYKEVSEPQDDDYL 1 2 YCEMCQNFFIDSCAAHGPPTFVKDSAVDKGHPNRSALSLPPGLRIGPSGIPQAGLGVWNEASDLPLGLHFGPYEGRITEDEEAANNGYSWL 0 0 ITKGRNCYEYVDGKDKSWANWMR 2 1 YVNCARDDEEQNLVAFQYHRQIFYRTCRVIRPGCELLVWYGDEYGQELGIKWGSKWKKELMAGR 1 2 EPKPEIHPCPSCCLAFSSQKFLSQHVERNHSSQNFPGPSARKLLQPENPCPGDQNQEQQYPDPHSRNDKTKGQEIKERSKLLNKRTWQREISRAFSSPPKGQMGSCRVGKRIMEEESRTGQKVNPGNTGKLFVGVGISRIAK VKYGECGQGFSVKSDVITHQRTHTGEKL YVCRECGRGFSWKSHLLIHQRIHTGEKP YVCRECGRGFSWQSVLLTHQRTHTGEKP YVCRECGRGFSRQSVLLTHQRRHTGEKP YVCRECGRGFSRQSVLLTHQRRHTGEKP YVCRECGRGFSWQSVLLTHQRTHTGEKP YVCRECGRGFSWQSVLLTHQRTHTGEKP YVCRECGRGFSNKSHLLRHQRTHTGEKP YVCRECGRGFRDKSHLLRHQRTHTGEKP YVCRECGRGFRDKSNLLSHQRTHTGEKP YVCRECGRGFSNKSHLLRHQRTHTGEKP YVCRECGRGFRNKSHLLRHQRTHTGEKP YVCRECGRGFSDRSSLCYHQRTHTGEKP YVCREDE* 0 >PRDM9_homNea Homo sapiens (neanderthal) variants R HDL S R 0 MSPEKSQEESPEEDTERTERKPM 0 0 VKDAFKDISIYFTKEEWAEMGDWEKTRYRNVKRNYNALITI 1 2 GLRATRPAFMCHRRQAIKLQVDDTEDSDEEWTPRQQ 1 2 VKPPWMALRVEQRKHQK 1 0 GMPKASFSNESSLKELSRTANLLNASGSEQAQKPVSPSGEASTSGQHSRLKL 1 2 ELRKKETERKMYSLRERKGHAYKEVSEPQDDDYL 1 2 YCEMCQNFFIDSCAAHGPPTFVKDSAVDKGHPNRSALSLPPGLRIGPSGIPQAGLGVWNEASDLPLGLHFGPYEGRITEDEEAANNGYSWL 0 0 ITKGRNCYEYVDGKDKSWANWMR 1 1 YVNCARDDEEQNLVAFQYHRQIFYRTCRVIRPGCELLVWYGDEYGQELGIKWGSKWKKELMAGR 2 2 EPKPEIHPCPSCCLAFSSQKFLSQHVERNHSSQNFPGPSARKLLQPENPCPGDQNQEQQYPDPHSRNDKTKGQEIKERSKLLNKRTWQREISRAFSSPPKGQMGSCRVGKRIMEEESRTGQKVNPGNTGKLFVGVGISRIAK VKYGECGQGFSVKSDVITHQRTHTGEKL YVCRECGRGFSWKSHLLIHQRIHTGEKP YVCRECGRGFSWQSVLLTHQRTHTGEKP YVCRECGRGFSRQSVLLTHQRRHTGEKP YVCRECGRGFSRQSVLLTHQRRHTGEKP YVCRECGRGFSWQSVLLTHQRTHTGEKP YVCRECGRGFSWQSVLLTHQRTHTGEKP YVCRECGRGFSNKSHLLRHQRTHTGEKP YVCRECGRGFRDKSHLLRHQRTHTGEKP YVCRECGRGFRDKSNLLSHQRTHTGEKP YVCRECGRGFSNKSHLLRHQRTHTGEKP YVCRECGRGFRNKSHLLRHQRTHTGEKP YVCRECGRGFSDRSSLCYHQRTHTGEKP >PRDM9_panTro Pan troglodytes (chimp) frag assembly glitch *VCREDE* 0 MSPERSQEESPEEDTERTERKPM 0 0 VKDAFKDISIYFTKEEWAEMGDWEKTRYRNVKRNYNALITI 1 2 GLRATRPAFMCHRRQAIKLQVDDTEDSDEEWTPRQQ 1 2 VKPPLMALRVEQRKHQK 0 0 GMPKASFSNESSLKELSRTANLLNASGSEQAQKPVSPPGEASTSGQHSRLKL 1 2 ELKKKETEGKMYSLRERKGHAYKEVSEPQDDDYL 1 2 YCEMCQNFFIDSCAAHGPPTFVKDSAVDKGHPNRSALSLPPGLRIGPSGIPQAGLGVWNEASDLPLGLHFGPYKGRITEDEEAANNGYSWL 0 0 ITKGRNCYEYVDGKDKSWANWMR 2 1 YVNCARDDEEQNLVAFQYHRQIFYRTCRVIRPGCELLVWYGDEYGQELGIKWGSKWKKELMAGR 1 2 EPKPEIHPCPSCCLAFSSQKFLSQHVERNHSSQNFPGPSARKLLQPENPCPGDQNQEQQYPDPRSRNDKTKGQEIKERSKLLNKRTWQREISRAFSSPPKGQMGSCRVGKRIMEEESRTGQKVNPGNTAKLFVGVGISRIAK VKYGECGQGFSVKSDVITHQRTHTGEKP YVCRECGRGFSWKSHLLSHQRTHTGEKP YVCRECGRGFSVKSSLLSHRTTHTGEKP YVCRECGRGFSVKSSLLSHQRTHTGEKP YVCRECGRGFSQQSNLLSHQRTHTGEKP YVCRECGRGFSVKSSLLSHQRTHTGEKP YVCRECGRGFSVKSSLLSHQRTHTGEKP YVCRECGRGFSKQSHLLSHQRTHTGEKP YVCRECGRGFSVQSNLLSHQRTHTGEKL YVCRECGRGFSQQSHLLRHQRTHTGEKP YVCR LLSHQRTHTGEKP YVCRECGRGFSVKSSLLSHQRTHTGEKP YVCRECGRGFSKQSHLLSHQRTHTGEKP YVCRECGRGFSQQSHLLSHQRTHTGEKP YVCRECGRGFSQQSHLLRHQRTHTGEKP YVCRECGRGFSVKSSLLSHQRTHTGEKP YVCRECGRGFSVKSSLLSHQRTHTGEKP YVCRECERGFSQQSHLLRHQRTHTGEKP YVCRECGRGFSRQSALLIHQRTHTGEKP* 0 >PRDM9_ponAbe Pongo abelii (orangutan) GEKPYVCRECGRGFSVKSNLLSHQRTHTEEKLYVCREDE* 0 MSPERSQEESPEDDTERTERKPT 0 0 VKDAFKDISIYFTKEEWAEMGDWEKTRYRNVKRNYNALITI 1 2 GLRATRPAFMCHRRQAIKLQVDDTEDSDEEWTPRQQ 1 2 VKPPWMALRVEQRKHQK 0 0 GMPKASFNNESSLKELSETANLLNASGSEQAQKPVSPPGEASTSGQHSRLKL 1 2 ELRSKETEGNTYSLRERKGHAYKEISEPQDDDYL 1 2 CEMCQNFFIDSCAAHGPPTFVKDSAVDKGHPNRSALTLPPGLRIGPSGIPQAGLGVWNEASDLPLGLHFGPYEGRITKDEEAANNGYSWL 0 0 ITKGRNCYEYVDGKDKSWANWMR 2 1 YVNCARDDEEQNLVAFQYHRQIFYRTCRVIRPGCELLVWYGDEYGQELGIKWGSKWKKELMAGR 1 2 EPKPEIHPCPSCCLAFSSQKFLSQHVERNHSSQNFPGPSARKLLQPENPCPGDQNHEQQYSDPRSCNDKTKGQEIKERSKLLNKRTWQREISRAFSSPPKGQMGSCRVGKRIMEEESRTGQKVNPGNTGKLFVGVGISRIAK VKYGECGQGFSVKSDVITHQRTHTGEKP YVCRECGRGFSRQSVLLIHQRTHTGEKP YVCRECGRGFSRRSVLLIHQRTHTGEKP YVCRECGRGFSQQSVLLIHQRTHTGEKP YVCRECGRGFSRRSVLLIHQRTHTGEKP YVCRECGRGFSWKSVLLRHQRTHTGEKP YVCRECGRGFSQQSVVFIHQRTHTGEKP YVCRECGRGFSGKSVLFRHQRTHTGEKP YVCRECGRGFSDKSGVCYHQRTHTRGEA LCLQGVWAGL* 0 >PRDM9_macMul Macaca mulatta (rhesus) 0 MSPERSQEESPEEDTERTERKPT 0 0 VKDAFKDISIYFTKEEWAEMGDWEKTRYRNVKRNYNALITI 1 2 GLRATRPAFMCHRRQAIKLQVDDTEDSDEEWTPRQQ 1 2 VKPPWMAVRVEQSKHQK 0 0 GMPKASFNNESSLKEVSGMANLLNTSGSEQAQKPVSPPGEARTSGQHSRLKL 1 2 ELRRKETEGKMYSLRERKGHAYKEVSEPQDDDYL 1 2 YCEMCQNFFIDSCAAHGPPTFIKDSAVEKGHPNRSALSLPPGLRIGPSGIPQAGLGVWNEASDLPLGLHFGPYEGRITQDEEAANNGYSWL 0 0 ITKGRNCYEYVDGKDKSWANWMR 2 1 YVNCARDDEEQNLVAFQYHRQIFYRTCRVIRPGCELLVWYGDEYGQELGIKWGSKWKKELMAGR 1 2 EPKPEIHPCPSCCLAFSSQKFLSQHVERNHSTQNFPGPSARRLFQPENLCSGDQNQEQQYSDPRSCNDKTKGQEIKERSKLLNKRTWPKEISRAFSSPPKGQMGSSRVGERMMEEEYRTGQKVNPENTGKLFVGVGISRIAK VKYGECGQGFSDKSDVIIHQRTHTGEKP YLCRECGRGFSQKSSLRRHQRTHTGEKP YLCRECGRGFRDNSSLRYHQRTHTGEKP YLCRECGRGFSNNSGLCYHQRTHTGEKP YLCRECGRGFSDNSSLHRHQRTHTGEKP YLCRECGRGFSNNSGLRYHQRTHTGEKP YLCRECGRGFSNNSGLRHHQRTHTGEKP YLCRECGRGFSQKANLLRHQRTHTGEKP YLCRECGRGFSQKADLLSHQRTHTGEKP* >PRDM9_calJac Callithrix jacchus (marmoset) one frameshift in repeat area chr20 terminus 0 MSPERSQEESPEGDTGRTEQKPM 0 0 VKDAFKDISMYFSKEEWAEMGDWEKTRYRNMKRNYNALITI 1 2 GLRATRPAFMCHRRQAIKLQVDDTEDSDEEWTPRQQ 1 2 VKPPGMAFRVGQSKHQK 0 0 GMPKASFGNESSLKKLSGTANVLNTSGPEQAQKPVSPPGEASTSGQHSRLKL 1 2 ELRRKDTEEKMYSLRERKGLAYKEVSEPQDDDYL 1 2 yCEICQNFFIDSCAAHGPPTFVKDSAVDKGHPNHAALSLPPGLRIGPSGIPQAGLGVWNEASDLPLGLHFGPYEGRVTEDEEAASSGYSWL 0 0 ITKGRNCYEYVDGKDKSWANWMR 2 1 YVNCARDDEEQNLVAFQYHRQIFYRTCRVIRPGCELLVWYGDEYGQELGIKWGSKWKKELMAGR 1 2 ESKPEIHPCPSCCLAFSSQKFLSHHVERNHSSQNFPGTSTRKLLQPENPCPGKQKEEQQYFDPCNSNDKTKGQETKERSKLLNIRTWQREMARAFSNPPKGQMGSSRVEERMMEEESRTGQKVNPVDTGKLFVGVGISRIAK AKYGECGQGFSDMSDVTGHQRTHTGEKP YVCRECGRGFSQKSALLSHQRTHTGEKP YVCRECGRGFSQKSHLLSHQRTHTGEKP YVCTECGRGFSQKSVLLSHQRTHTGEKP YVCTECGRGFSRKSNLLSHQRTHTGEKP YVCRECGRGFSRKSALLSHQRTHTGEKP YVCRKCGRGFSQKSNLLSHQGTHTGEKP YVCTECGRGFSQKSHLLSHQRTHTGEKP YVCRKCGRGFSQKSNLLSHQRTHTGEKP YVCRECGRGFSFKSALLRHQRTHTGEKP YVCRECGRGFSRKSHLLSHQGTHIGEKP YVCRECGRGFSRKSNLLSHQRIHTGEKP YVRREDE* >PRDM9_musMus Mus musculus (mouse) Q96EQ9 0 MNTNKLEENSPEEDTGKFEWKPK 0 0 VKDEFKDISIYFSKEEWAEMGEWEKIRYRNVKRNYKMLISI 1 2 GLRAPRPAFMCYQRQAMKPQINDSEDSDEEWTPKQQ 1 2 VSPPWVPFRVKHSKQQK 0 0 ESSRMPFSGESNVKEGSGIENLLNTSGSEHVQKPVSSLEEGNTSGQHSGKKLKL 1 2 RKKNVEVKMYRLRERKGLAYEEVSEPQDDDYL 1 2 YCEKCQNFFIDSCPNHGPPLFVKDSMVDRGHPNHSVLSLPPGLRISPSGIPEAGLGVWNEASDLPVGLHFGPYEGQITEDEEAANSGYSWLITKGRNC 1 2 YEYVDGQDESQANWMR 2 1 YVNCARDDEEQNLVAFQYHRKIFYRTCRVIRPGCELLVWYGDEYGQELGIKWGSKMKKGFTAGR 1 2 ELRTEIHPCLLCSLAFSSQKFLTQHMEWNHRTEIFPGTSARINPKPGDPCSDQLQEQHVDSQNKNDKASNEVKRKSKPRQRISTTFPSTLKEQMRSEESKRTVEELRTGQTTNTEDTVKSFIASEIS SIERQCGQYFSDKSNVNEHQKTHTGEKP YVCRECGRGFTQNSHLIQHQRTHTGEKP YVCRECGRGFTQKSDLIKHQRTHTGEKP YVCRECGRGFTQKSDLIKHQRTHTGEKP YVCRECGRGFTQKSVLIKHQRTHTGEKP YVCRECGRGFTQKSVLIKHQRTHTGEKP YVCRECGRGFTAKSVLIQHQRTHTGEKP YVCRECGRGFTAKSNLIQHQRTHTGEKP YVCRECGRGFTAKSVLIQHQRTHTGEKP YVCRECGRGFTAKSVLIQHQRTHTGEKP YVCRECGRGFTQKSNLIKHQRTHTGEKP YVCRECGWGFTQKSDLIQHQRTHTREK* 0 >PRDM9_ratNor Rattus norvegicus (rat) P0C6Y7 0 MNTNKPEENSTEGDAGKLEWKPK 0 0 VKDEFKDISIYFSKEEWAEMGEWEKIRYRNVKRNYKMLISI 1 2 GLRAPRPAFMCYQRQAIKPQINDNEDSDEEWTPKQQ 1 2 VSSPWVPFRVKHSKQQK 0 0 ETPRMPLSDKSSVKEVFGIENLLNTSGSEHAQKPVCSPEEGNTSGQHFGKKLKL 1 2 RRKNVEVNRYRLRERKDLAYEEVSEPQDDDYL 1 2 YCEKCQNFFIDSCPNHGPPVFVKDSVVDRGHPNHSVLSLPPGLRIGPSGIPEAGLGVWNEASDLPVGLHFGPYKGQITEDEEAANSGYSWLITKGRNC 1 2 YEYVDGQDESQANWMR 2 1 YVNCARDDEEQNLVAFQYHRKIFYRTCRVIRPGRELLVWYGDEYGQELGIKWGSKMKKGFTAGR 1 2 ELRTEIHPCFLCSLAFSSQKFLTQHVEWNHRTEIFPGASARINPKPGDPCPDQLQEHFDSQNKNDKASNEVKRKSKPRHKWTRQRISTAFSSTLKEQMRSEESKRTVEEELRTGQTTNIEDTAKSFIASETS RIERQCGQCFSDKSNVSEHQRTHTGEKP YICRECGRGFSQKSDLIKHQRTHTEEKP YICRECGRGFTQKSDLIKHQRTHTEEKP YICRECGRGFTQKSDLIKHQRTHTGEKP YICRECGRGFTQKSDLIKHQRTHTEEKP YICRECGRGFTQKSSLIRHQRTHTGEKP YICRECGLGFTQKSNLIRHLRTHTGEKP YICRECGLGFTRKSNLIQHQRTHTGEKP YICRECGQGLTWKSSLIQHQRTHTGEKP YICRECGRGFTWKSSLIQHQRTHTVEK* 0 >PRDM9_turTru Tursiops truncatus (dolphin) 0 MSTDRWPEDSTEGDAGRTAWKPT 0 0 VKDAFKDISIYFSKEEWTEMGEWEKIRYRNVKKNYEALVTL 1 2 GLRAPRPAFMCHRRQAIKAQVGDPEDSDEEWTPRQQ 1 2 VKPSWVAFRVEHSKHQK 0 0 AVPPVPLSNESSLKKLPGAAQLQKASGPAQAQSPAPPPGAASTSAWHTRQKL 1 2 ERRAKQIEVKMYSLRERKGHVYQEVSEPQDDDYL 1 2 yCEKCQNFFIDSCAAHGAPTFVKDSAVEKGHPNRSALTLPPGLSIRPSGIPEAGLGVWNEASDLPLGLHFGPYEGQITEDEEAANSGYSWL 0 0 ITKGRNCYEYVDGKDTSWANWMR 2 1 YVNCARDEEEQNLVAFQYHRQIFYRTCRVVRPGCELLVWYGDEYSQELGIPWGSGWKSQLVAAGR 1 2 DPKPKIQPCGSCSLAFSSQKILSQHVECSHPSQVLPRTSARDRVQPEDPCPGYQNRQQQYSDPHSWSNKPECQEVKERSKPLLKRIRLGRISRAFSSSPKGQMGSSRAHERMMEAGPSTGQKVNPEATGKLLIGAGVSRVVK VKYRSSGQGSKDRSSLTKHQRTHTGEKP YVCGECGRDFSLKSDLIRHQRTHTGEKP YVCGECGRDFSLKSGLISHQRTHTGEKP YVCGECGRDFSQKSGLIRHQRTHTGEKP YVCGECGRDFSLKSGLISHQRTHTGEKP YVCGECGRDFSQKSGLIRHQRTHTGEKP YVCGECGRDFSLKSGLITHQRTHTGEKP YVCGECGRDFSQKSNLITHQRTHTGEKP YVCGECGRDFSRKSSYI* 0 >PRDM9_pteVam Pteropus vampyrus (bat) pseudogene 2 LRRKGVEVKMDSLRERMGRVYQEVSEPQDDDYL 1 2 CEKCQNFFIDSCAAHGSPIFVKDSEVDIGHPNHSALTLPPGLRIGPSGIPEAGLGVWNEASNLPLGLLFGPYEGQVTEDEEAANSKYS*M 0 0 spKGETAEYVDGKDESRANWMR 2 1 YVNCARDDEDQNLVAFQFRRQIFYRTCRVIMPGCELLVWYGDEYGQGLGIKWGSKWKREFTAGR 1 2 EPKPEIHPCPSCSLAFSSRKFLSQHMKRSHPSQSLPGISARKHLQSKEPHPEDQSQQQQQQQHTDPCSWNDKAEGQEVKERSKPMLERNGQRKISRAFSKPPKGQMGSPRECERMMEAEPSTSQKVNPENTGKSSVGVGASRIVR VKYGGCGHGFDDGSHFIRHQRTHSGEKP FVCRECERGFNEKSSLTMHQRTHSGEKP FVCRECE*GFSVKSSLIRHQRTYSGEKP FVCRECEQGFNEKSSLTMHQRTHSGEKP FFCRECE*GFSVKSSLIRHQRTHSGQKP FVCRECKRGFTQKSHLITHQRTHSGEKP FAGSVSEALHKSHISSSTRGHTQGRSPLFAGSVRESLALNCISTATGQM* >PRDM9a_bosTau Bos taurus (cattle) NW_003053109 chr 1 0 MRPNTSPEESTERDAGRTEWKPT 0 0 AKDAFKDISVYFSKEEWEEMGEWEKIRYRNVKRNYEALIAI 1 2 GFRATRPAFMHHRRQVIKLQADDTEDSDEEWTPRQQ 1 2 GKLSSMAFRVEHNKHQN 0 0 TMSRAPLSKEFSLKELPGAAKLLKTSGSKQAQKLVPPPGKARTPGQHPRQKV 1 2 ELRRKETEVKRYSLRERKGHVYQEVSEPQDDDYL 1 2 YCEECQSFFIDSCAAHGPPIFVKDCAVEKGHANRSALTLPPGLSIRESSIPEAGLGVWNEVSDLPLGLHFGPYEGQITDDEEAANSGYSWL 0 0 ITKRRNCYEYVDGKDTSLANWMR 2 1 YVNCARDDEEQNLVALQYHGQIFYRTCQVVRPGCELLVWYGDEYGQDLGIKRESSRKSELAGPR 1 2 ESKPKIHPCASCSLAFSSQKFLSQHVQHNHPSQTLLRPSARDYLQPEDPCPGSQNQQQRYSDPHSPSDKPEGREVKDRPQPLLKSIRLKRISRASSYSPRGQMGASGVHERITEEPSTSQKPNPEDTGKLFMGAGVSGIIK VKYGECGQGSKDRSSLITNQRTHTGEKP YVCGECGQSFNQKSTLITHQRTHTGEKP YVCGECGRSFNQKSTLITHQRTHTGEKP YVCGECGRSFSQKSTLIKHQRTHTGEKP YVCGECGQSFNQKSTLITHQRTHTGEKP YVCGECGQSFNQKSTLITHQRTHTGEKP YVCGECGRSFSRKSTLITHQRTHRGEKL CLQGV* 0 >PRDM9b_bosTau Bos taurus (cattle) DAAA02065087 chr Un.004.649; aaaaa fixed to aaaaaa in exon 2 KRAB SSXRD SET C2H2 0 MRPNRSPEESTEGDAGRTEWKPM 0 0 AKDAFKDISIYFSKEEWEEMGEWEKIRYRNVKRNYEVLITI 1 2 GFRAARPAFMHHRRQVIKPQVNDIKDSDEEWTPRQQ 1 2 GKPFSMAFRVEHSKHQK 0 0 KGMSRAPLSKESSLKELPGAAKLLKTSGCKQAQKLVPPPRKARTPEQHPRQKV 1 2 ERRRKETGVKRYSLREREGLVYQEVSEPLDDDYL 1 2 YCEECQSFFIDICAAHRPPTFVKDCAVEKGHANCSALTLPPGLSIRLSGIPEAGLGVWNEASDLPLGLHFGPYEGQITDDKEAAHSRYSWL 0 0 ITKGRNCYEYVDGKDTSLANWMR 2 1 YVNCARDDEEQNLVALQYQGQIFYRTCQVVRPGCELLVWYGDEYGWDLSIKQDSRGKNKLAAGR 1 2 AKMHPCASCSLAFSSQKFLSQHVQRNHPSQTLLRPSARDHLQPEDPCPGNQNQQQRYSDPHSPSDKPEGRKAKDRPQPLLKSIKLKRISRASSYSPRGQVGRSGVHERITEEPSTSQKLNPEDTGKLFMGAGVSGIIK VKYRECGQGSKDRSSLITHERTHRAEAL CLRRVWAKLQSEVPLLVMHQRTHTGEKL YVCGECGKSFSQKSPLIRHQRTHTGEKP YVCGECGKSFSQKSPLIRHQRTHTGKKP YVCRECGRSFSDKSHHT PEYTHRGEAL HLRGVWAKLQCQVQAHQTPEDTHRGAALCLQRV* 0 >PRDM9c_bosTau Bos taurus (cattle) chrX or Un.004.251 XM_002699750 4-cell embryo transcript GO353654 no zinc downstream despite 43k bp; KRAB SSXRD SET 0 MSQNRSPEERTKGDAGRTEWKLT 0 0 AKDAFKDISIYFSKEEWAEMGEWEKTGYRNVKRNYEVLIAI 1 2 GLRATQPAFMHHRRQVIKPQGDDTEDSDEEWTPQHQ 1 2 GKPSRKAFRMEHRKHQK 0 0 GKSRGPLSKVSSLKKLQGAAKLLNTSGSKWAQKPANPPRETRTLEQHSRQKV 1 2 ELRRKETDMKRYSLRERKGHVYQEVSEPQDDDYL 1 2 YCQECQNFFIDSCDAHGPPTFVKDSAVEKGHANRSVLTLPPGLSIKLSGIPEAGLGVWNEASHLPLGLHFGPYEGQITDDKEAINSGYSWL 0 0 ITKGRNSYEYVDGKDTSLaNWMR 2 1 YVNCARHYEEQNLVAFQYHGQIFYRTCQVVRPGCELLVWYGDEYGEKLGIKCESRGKSMFAAGGVEGHPSSSTPPHSGELPR* 0 >PRDM9d_bosTau Bos taurus (cattle) chrX proximal tandem 0 MSPNRSPENSTEGDAGRTEWKPM 0 0 AKDAFKDISIYFTKEEWAEMGEWEKIQYRNVKRNYEALIAI 1 2 GFRATQPGFMHHGRQVLKSQVDDTEDSDEEWTPRQQ 1 2 GKPSGMAFRGEPSKHPK 0 0 RLSRGPLNKVSSLKKLPGAAKLLKKSGSKQAQKPVPPPREARTPGKHPRHKV 1 2 ELRRKETEVKRYSVRERKGHVYQEVSEPQDDDYL 1 2 YCEECQNFFIDSCAAHGPPTFVKDSAVEKGHANRSALTLPPGLSIRPSGIPEAGLGVWNEASDLPLGLHFGPYEGQIIYNEEDSNSGYCWL 0 0 VTKGRNSYEYVDGKDTSLANWMR 2 1 YVNCARDDEEQNLVALQYHGQIFYRTCRVVRPGCELLVWYGDEYGEELGIKQDKRGKSKLSAQR 1 2 EPKPKIYPCASCCLSFSSQKFLSQHVQRNHPSQILLRPSIGDHLQPEDPCPGSQNQQQRYSDPHSLSDKPEGREPKERPHPLLKGPKLCIRPKRISTASSYPPKGQMGGSEVHERMTEEPSTSQKLNPEDTGKLFMEAGVSGIVR VNYGDHEQGSKDRSSLITHEKIHTGEKP YVCKECGKSFNGRSDLTKHKRTHTGEKP YACGECGRSFSFKKNLITHKRTHTREKP YVCRECGRSFNEKSRLTIHKRTHTGEKP YVCGDCGQSFSLKSVLITHQRTHTGEKP YVCGECGRSFNEKSRLTIHKRTHTGEKP YVCGDCGQSFSLKSVLITHQRTHTGEKP YVCGECGQSFNEKSRLTIHKRTHTGEKP YACGDCGQSFSLKSVLITHQRTHTGEKP YVCMECE* 0 >PRDM9e_bosTau Bos taurus (cattle) chrX distal tandem 0 MSPNRSPENSTEGDAGRTEWKPM 0 0 AKDAFKDISIYFTKEEWAEMGEWEKIRYRNVKRNYEALIAI 1 2 GFRATQPGFMHHRRQVLKPQVDDTEDSDEEWTPRQQ 1 2 GKPSGMAFRGERSKHQK 0 0 RLSRGPLNKVSSLKKLPGAAKLLKKSGSKQAQKPVPPPREARTPGKHPRHKV 1 2 ELRRKETKVKRYSVRERKGHVYQEVSEPQDDDYL 1 2 YCEECQNFFIDSCAAHGPPTFVKDSAVEKGHANRSALTLPPGLSIRPSGIPEAGLGVWNEASDLPLGLHFGPYEGQIIYNEEDSHSGYCWL 0 0 VTKGRNSYEYVDGKDTSLANWMR 2 1 YVNCARDDEEQNLVALQYHGQIFYRTCRVVRPGCELLVWYGDEYGEELGIKQDKRGKSKLSAQR 1 2 EPKPKIYPCASCCLSFSSQKFLSQHVQRNHPSQILLRPSIGDHLQPEDPCPGSQNEQQRYSDPHSLSDKPEGREPKERPHPLLKGPKLCIRLKRISTASSYPPKGQMGGSEVHERMTEEPSTSQKLNPEDTGKLFMEAGVSGIVR VKYGEHEQDSKDKSSLITHEKIHTGEKP YVCTECGKSFNWKSDLTKHKRTHSEEKP YACGECGRSFSFKKNLIIHQRTHTGEKP YVCGECGRSFSEKSNLTKHKRTHTGEKP YACGECGQSFSFKKNLITHQRTHTGEKP YVCGECGRSFSEKSRLTTHKRTHTGEKP YVCGDCGQSFSLKSVLITHQRTHTGEKP YVCRECGRSFSVISNLIRHQRTHTGEKP YVCRECEQSFREKSNLVRHQRTHTGEKP YVCMECE* 0 >PRDM9a_bosGru Bos grunniens (yak) testis transcript EF432551 nearly identical PRDM9a_bosTau 2 NRSALTLPPGLSIRESSIPEAGLGVWNEVSDLPLGLHFGPYEGQITDDEEAANSGYSWL 0 0 ITKRRNCYEYVDGKDTSLANWMR 2 1 YVNCARDDEEQNLVALQYHGQIFYRTCQVVRPGCELLVWYGDEYGQDLGIKRESSRKSELAAPR 2 ESKPKIHPCASCSLAFSSQKFLSQHVQHNHPSQTLLRPSARDYLQPEDPCPGSQNQQPRYSDPHSPSDKPEGREVK >PRDM9_oviAriX1 Ovis aries (sheep) 0 MSPNRSPENSTEGDAGRTEWKPM 0 0 AKDAFKDISIYFTKEEWAEMGEWEKIRYRNVKRNYEALIAI 1 2 GFRATQPAFMHHHRQVIKPQVDDTEDSEEEWTPRQQ 1 2 GKPSGMAFRGERSKHQK 0 0 RLSRGPLNKVSSLKKLPGAAKLLKKTGSKQAQKPVPPPREARTPGQHPRHKV 1 2 ELRRKETEVKRYSLRERKGHVYQEVSELQDDDYL 1 2 CEECQNFFIDSCAAHGPPTFVKDSAVEKGHANRSALTLPPGLSIRPSGIPEAGLGVWNEASDLPLGLHFGPYEGQVIYNEEASHSGYSWL 0 0 VTKGRNSYEYVDGKDTSLANWMR 2 1 YVNCARDDEEQNLVALQYHGQIFYRTCQVVRPGCELLVWYGDEYGEELGIKQDSRGKSKLSAQR 1 2 EPKPKIHPCASCSLSFSSQKFLSQHVQRSHPSQILLRPSPRDHLQPEDPCPGKQNQQQRYSDPHSPSDKPEGQEPKERPHPLLKGPKLCIRLKRISTASSYTPKGQMGGSEVHEKMTEEPSTSQKLNPENTGKLFMEAGVSGIVR VKYGEHEQGSKDKSSLITHERIHTGEKP YVCKECGKSFNGRSNLTRHKRTHTGEKP YVCRECGQSFSLKSILITHQRTHTGEKP YVCGECGQSFSEKSNLTRHKRTHTGEKP YVCRECGQSFSLKSILITHQRTHTGEKP YVCRECGRSFSVKSNLTRHKMTHTGEKP YVCGECGQSFSQKPHLIKHQRTHTGEKP YVCRECGRSFSAMSNLIRHQRTHTGEKP YVCRECGRSFSAMSNLIRHQRTHTGEKP YVCREC* 0 >PRDM9_oviAriX2 pseudogene 0 MSPNRSPENSTEGDAGRTEWKPM 0 0 AKDAFKDISIYFTKEEWAEMGEWEKIRYRNVKRNYEALIAI 1 2 GFRATQPAFMHHHRQVIKPQVDDTEDSEEEWTPRQQ 1 2 GKPSGMAFRGERSKHQK 0 0 GMSRGPLSKVSSLKKLPGTTKLLKTSGSKQAQKPVPSSREARTSG*HTRQKV 1 2 ELGRKETDMKRYSLRERKGHVYQEVSEPQDDDYL 1 2 CQECQNFFINSCDAHGPPTFVKDSAVEKGHANRSALTLPPGLSIRLSGIPEAGLGVWNEASHLPLGLHFGPYEGQITDDKEAVNSGYSWL 2 1 YVNCARHYEEQNLVAFQYHGQIFYRTCQVVRPGCELLVWYGDEYGEKLGIRCESRGKSMLAAGR 1 2 EPKPKIYPCASCCLSFSSQKFLSQHVQRNHPSQILLRPSIGDHLQPEDPCPGSQNEQQ*YSDPHSPSDKPEGCKAKERPPWLLKSMSV-----RISMASSYSPKGQMRGSETHYRMTEEPSTSQKLNPEDIGKLFMGTGVSGIIK IKYEECGQVSKDRSSLITHEGTHTREQ >PRDM9_sorAra Sorex araneus (shrew) AALT01000095 0 MSLNRPAEMNTQGKARKLMLKPM 0 0 SKDAFKDISMYFSKEEWAEMGDWEKIRHRNVKRNYEELISI 1 2 GLRAARPAFMSHRRQAIKTQLDDTEESDEEWTPNQQ 1 2 VKSLRVAFRAEQSKHQK 0 0 GRSRTPISNESSSKELSGTRTLLNTKCTKQAQKPLFPPGEASTSGHYSKPKL 1 2 ELRRKEPEVKMYSLRERKGRAYQEVSEPQDDDYL 1 2 YCENCQNFFINKCSAHGSPIFVKDNAVAKGHSNRSALTLPHGLRIGPSGIPEAGLGIWNEASDLPLGLHFGPYEGQITNDEEAANSGYSWL 0 0 ITKGRNCYEYVDGVDESLANWMR 2 1 YVNCARDYEEQNLVAFQYHRQIFYRTCRIIKPGCELLVWYGDEYGQELGIKWGSKWKSELTADK 1 2 EPKPEIYPCPCCSLAFSNQKFLSRHVEHSHPSLILPGTSARTHPKSVNFCPGDQNQWQQHSDACNDKPDEPWNDKLENHKSKGRSKPLPKRMGQKRISTAFPNLRSSKMGSSNKHETIMDKINTGQKENPKDTYRVFAGIGMPRIIR DKHVTLRRSFTNRSSPLTHQRTHTGEKP YVCRECGRGFSQKSHLLTHQRTHTGEKP YVCRECGRGFTDRSSLLTHQRTHTGEKP YVCRECGRGFSLKSSLLRHQRTHTGEKP YVCRECGRGFSLKSSLLTHQRTHTGEKP YVCRECGRGFTDRSSLLTHQRTHTGEKP YVCRECGRGFSLKSSLLTHQRTHTGEKP YVCRECGRGFSRKSSLLRHQRTHTGEKPYVCES* 0 >PRDM9_loxAfr Loxodonta africana (elephant) 0 MSPARAAKKNPRGDVGSAGRTPT 0 0 aKDTFRDISIYFSKEEWAEMGEWEKFRYRNVKRNYEALVTI 1 2 GLRAPRPAFMCHRRQAIKAQVDNTEDSDEEWTPRQQ 1 2 VKPPSVASRAEQSRHQK 0 0 GTPKALLGNESSLKEVSGTAILLNTTGSEQAQKPVSSPGEASTSDQPSRWKL 1 2 EPRRNEVEVKMYNLRERKGLEYQEVSEPQDDDYL 1 2 yCEKCQNFFIDTCAVHGAPMFVKDSPVDRGHPNHSALTLPPGLRIGPSSIPKAGLGVWNEASELPLGLHFGPYEGQVTEDKEAANSGYSWL 0 0 ITKGKNCYEYVDGKDESWANWMR 2 1 YVNCARDEEEQNLVAFQYHRQIFYRTCRTIQPDCELLVWYGDEYGQELGIKWGSRWKKELTSGR 1 2 EPKPEIHPCPSCRLAFSSQKFLSQHMKHSHPSPPFPGTPERKYLQPEDPRPGGRRQQRSEQHMWSDKAEDPEAGDGSRLVFERTRRGCISKACSSLPKGQIGSSREGNRMMETKPSPGQKANPEDAEKLFLGVGTSRIAK VRCGECGQGFSQKSVLIRHQKTHSGEKP YVCGECGRGFSVKSVLIKHQRTHSGEKP YVCGECGRGFSVKSVLITHQRTHSGEKP YVCGECGRGFSVKSVLITHQRTHSGEKP YVCGECGRGFSQKSDLIKHQRTHSGEKP YSCRECGRGFSRKSVLITHQRTHSGEKP YVCGECGRGFSQKSNLITHQRTHSGEKP YVCGECGRGFSRKSVLITHQRTHSGEKP YVCGECGRGFSQKSNLITHQRTHSGEKP YVCGECGRGFSQKSDLITHQRTHSGEKP YVCRECGRGFSRKSNLITHQRTHSGEKP YVCRECRRGFSVKSALIGHGRRKCSKSAEPLHFPRVSRDQK* 0 >PRDM9_macEug Macropus eugenii (wallaby) fragment 2 gFSAPRPTFMCHGKQNKEAKVEESGDFDEEWIRKQP 1 2 CEECQTFFLETCAVHGPPKFVQDSVMVKGHPYCSAITLPPGLRIGLSGIPGAGLGIWNEASNLPLGLHFGPYEGQMTEDDEAANSGYSWM 0 1 YVNCARDEEEQNLVAFQYHRKIFYRTCQIIRPGCELLVWYGDEYGQELGIKWGSKWKRPPITLT 1 >PRDM9_monDom Monodelphis domestica (opossum) not at GAS8 weak C2H2 domain fragment 0 GEDAFKDISTYFSKKQWVKLKEWEKVRLKNVKRNYEAMIKI 1 2 GLSVPRPAFMCRGRQNKKVKVEESGDSDEEWIPKQL 1 2 DCRRKDVEVHIYSLRERKYQVYQEMWDPQDDDYL 1 2 yCEECQIFFLDSCPLHGPPTFVQDSAMVKGHPYCSAITLPPGLRIGLSGIPGAGLGVWNEASTLPLGLHFGPYKGKMTEDDEAANSGYSWM 0 0 ITKGRNCYEYVDGKEESCSNWMR 2 1 YVNCARDEEEQNLVAFQYHRQIFYRTCRVIRPGCELLVWYGDEYGQELGIKWGSKWKRPLPELTGE 1 2 EARNLSLPFHPLGFSTHTFLNQHTLLKTAPLSVLGFRDRKIMSWEIYSRTSYLQPVPTVK KECE*GFTHQTNLVTHRWTHSGERPYVCV* >PRDM9a_ornAna Ornithorhynchus anatinus (platypus) fragment RIGKKPQVRDFNLRKQKRKIYNENYRPEDDDYL CEICQTFFLEKCVLHGPPVFVQDLPVEKWRPNRSTITLPPGMQIKVSGIPNAGLGVWNQATSLPRGLHFGPYMGIRTKNEKESHSGYSWMI IVRGKNYEYLDGKDKAFSNWMR YVNCARSEREQNLVAIQYQGEIYYRTCRVIPPGQELLVWYGLEYGRHLG EARPSRYRDVVFSSGVYGSSVTLLTSGVP >PRDM9b_ornAna Ornithorhynchus anatinus (platypus) tandem fragment RSGKKPQVRDFNLRKQKRKMYTEESEPEDDDYL CEDCQTFFLEKCSVHGPPVFVQDCEAKRCQQNRSEVTLPPGLLIKMSGIPNAGLGVWNQATSLPRGLYFGPFVGIRKNNVKDSLSGYSWAV ILRGRNYEYLDGKNTSFSNWMR ASDSWTGRERLILLPSWGVGGAASGGKRVREDSGKGGWRESR KPVSALTTSWDSDGWERAADEVTVSLLPGERPHSSGGSFAPSARSGGVKQRIWSKRRSAA LQRTRERRNSTHDFPPKHEDTAARQDERQCPDRGRAKQRGVRKSEQIERAKAMGRKKALG GLSPPRRERLSDEAGQRKKSGHEQFWQKPGPSEAWAGPAEGSTIPRR HCCDVCGKAFNRLSRLKQHKRVHTGEKP LVCKICKRAFSDPSNLNRHAKRHTGEKP FVCRVCGRSFNRSDNMNEHRWKHTSNNIIP NTGHMSATVVENASLCINRNYQIYKERATYL- HCCDVCRKAFKRLSHLRQHKRIHTGEKP LVCKVCRRTFSDPSNLNRHSRIHTGLRP YVCKLCRKAFADPSNLKRHVFSHTGHKP FVCEKCGKGFNRCDNLKDHSAKHSEDNSTPKP* >PRDM7_homSap Homo sapiens (human) chr16:90,122,976 TUBB3+ DEFB+ AFG3L1+ DBNDD1- GAS8+ PRDM7- 92% identical 0 MSPERSQEESPEGDTERTERKPM 0 0 VKDAFKDISIYFTKEEWAEMGDWEKTRYRNVKMNYNALITV 1 2 GLRATRPAFMCHRRQAIKLQVDDTEDSDEEWTPRQQ 1 2 VKPPWMAFRGEQSKHQK 0 0 GMPKASFNNESSLRELSGTPNLLNTSDSEQAQKPVSPPGEASTSGQHSRLKL 1 2 ELRRKETEGKMYSLRERKGHAYKEISEPQDDDYL 1 2 YCEMCQNFFIDSCAAHGPPTFVKDSAVDKGHPNRSALSLPPGLRIGPSGIPQAGLGVWNEASDLPLGLHFGPYEGRITEDEEAANSGYSWL 0 0 ITKGRNCYEYVDGKDKSSANWMR 2 1 YVNCARDDEEQNLVAFQYHRQIFYRTCRVIRPGCELLVWYGDEYGQELGIKWGSKWKKELMAGR 1 2 EPKPEIHPCPSCCLAFSSQKFLSQHVERNHSSQNFPGPSARKLLQPENPCPGDQNQERQYSDPRCCNDKTKGQEIKERSKLLNKRTWQREISRAFSSPPKGQMGSSRVGERMMEEESRTGQKVNPGNTGKLFVGVGISRIAK VKYGECGQGFSDKSDVITHQRTHTGGKP YVCRECGR FSRKSDLLSHQRTHTGEKP YVCRECERGFSRKSVLLIHQRTHRGDAP VCRKDE* >PRDM7_panTro Pan troglodytes (chimp) pseudogene GAS8 0 MSPERSQEESPEGDTERTERKPM 0 0 VKDAFKDISIYFTKEEWAEMGDWgKTRYRiVKMNYNALITi 1 2 GLRATRPAFMCHRRQAIKLQVDDTEDSDEEWTPRQQ 1 2 VKPPWMAFRGEQSKHQK 0 0 GMPKASFNNESSLkELSGmPNLLNTSgSEQAQKPVSPPGEASTSGQHSRLKL 1 2 ELRRKETvGKMYSLRERKGHAYKEISEPQDDDYL 1 2 yCEMCQNFFIDSCAAHGPPTFVKDSAVDKGHPNRSALSLPPGLRIGPSGIPQAGLRVWNEASDPPLGLHSGPYEGQITEDEEAANSGYSWL 0 0 ITKGRNCYEYVDGKDKSwANWMR 2 1 YENCARDDEEQNLVSFQYHRQS*FYRTCRVIRPGCELLVWYGDE*GQELGIKWGSKWKKELMAGR 1 2 EPKPEIHPCPSCCLAFSSQKFLSQHVERNHSSQNFPGPSARKLQPENP*PGDQNQERQYSDPRCCNDKTKGQEVKERSKLLNKWTWQREISRAFSSLPKGQMGSSRVGERMMEEESRTGQKVNPGNTGKLFVGVGISRIAK VKYGECGQGFSDKSDVITHQRTHTGGKP YVCRECGQGFSRKSVLLIHQRTHRGEKP* 0 VCRKDE >PRDM7_ponAbe Pongo abelii (orangutan) GAS* 0 MSPERSQEESPkGDTERTERKPM 0 0 VKDAFKDISIYFTKEEWTEMGDWEKTRYRNVKRNYKTLITI 1 2 GLRATRPAFMCHRRQAIKLQVDDTEDSDEEWTPRQQ 1 2 VKPPWMAFRGEQSKHQK 0 0 GMPKASFNNESSLKELSGTQNLLNTSGSEQAQKPVSPPGEASTSGQHSTLKI 1 2 ELRRKETEGKTYSLRERKGHAYKEVSEPQDDDYL 1 2 YCEMCQNFFIDSCAAHGPPTFVKDSAVDKGHPNRSALSLPPGLRIGPSGIPQAGLGVWNEASDLPLGLHFGPYEGRITEDKEAANNGYSWL 0 0 ITKGRNCYEYVDGKDKSWANWMR 2 1 YVNCAWDDEEQNLVAFQYHRQIFYRTCRVIRPGCELLVWYGDEYGQELGIKWGSKWKKELMPGR 1 2 EPKPEIHPCPSCCLAFSSQKFLSQHVERNHSSQNFPGPSARHLLQAENPCPGDQNQEQQYSDPDCCNDKTKGQEIKERSKLLNKRTWQREISRAFSSSAKGQMGSSRVGERMMEEESGTGQKVNPGNTGKLFVGVGISRIAK VKYGECGQGFSDKSDVITHQRTHTGGRS YICRESGRGFTQKSGLLSHQRTHTGEKP YVCRECGWGFSQKSNLLRHQRTHTGEKP YVCRECGRGFSRKSVLLIHQRTHTGEKP* VCRKDE* >PRDM7_nomLeu Nomascus leucogenys (gibbon) ADFV01125891 no info GAS8 pseudogene 0 MSPERSQEESPkGDTERTERKPM 0 0 VKDAFKDISIYFTKEEWTEMGDWEKTRYRNVKRNYKTLITI 1 2 GLRATRPAFMCHRRQAIKLQVDDTEDSDEEWTPRQQ 1 2 IKSPWMAVRVEQSKHQK 0 0 GMPKASFNNESGLKELSGTQNLLNTSG*EQARKPVSPPGEASTSGQHSRQKL 1 2 ELRRKETEGKMYSL*ERKGHAYKEVSEPQDDDYL 1 2 yCEMCQNFFTDSCAAHGPPTFVKDSAVDKGHPNHSALSLPPGLRIGPSGIPQAGLGVWNEASDLPLGLHFGPYEGRITEDEEAANNGYSWL 0 0 ITKGRNCYEYVDGKDKS*ANWMK 2 1 YVNCARDHEEQNLVAFQYHRQIFYRTCQVIRPGCEPLVWYGDEYGQELGIKWGSKWKKELTAER 1 2 EPKPEIHPCPSCCLVFTSQKFLSQHVECNHSSQNFPGPSARKLLQRENPCPGDQNQEQQYSDSRSCNDKTKGQEIKERSKL*NKRIWQRKISRAFSSLPKGQMGSSRVGERMMEEESRTGQKVNPGNTGKLFVGVGISRIAK VKYGECGQGFSDKSDVIAHQGTHTGGKS *ICRECGWGFSQESHLLIHQRTHTGEKL YVCRECGQGFSQKSDLLSHQRTHTGEKP YVRRECGRGFSQKSNLLSHQRTHTEEKP YVCRECGWGFSQKSHLLIHQRTHTGKKP* VCRKDE >PRDM7_macMul Macaca mulatta (rhesus) pseudogene 0 MSPERSQEESPEEDTERTERKPT 0 0 VKDAFKDISIYFTKEEWAEMGDWEKTRYRNVKRNYNALITI 1 2 GLRATRPAFMCHRRQAIKLQVDDTEDSDEEWTPRQQ 1 2 VKPPWMAFRVEQSKHQK 0 0 EMPKTSFNNESSLKELSGTPNLLSTSDSE*AQKPASPPGEASTSGQHSRLKL 1 2 ELRRKETEGKMYSLRERKRHAYKEASELQHDDYL 1 2 YCEMCQNFFIDSCAAHGPPTFVKDNAVNKGHPNRSALSLPPGLRIGPSGIPQAGLGVWNEASDLPLGLHFGPCEGRITEDKEAANSGYSWL 0 0 ITKGRNCYEYVDGKDKSWAKWMR 2 1 YVNCARDDEEQNLVAFQYHRQIFYRTCRVIRPGCELLVWYGDEYGQELGIKWGSKWKKELMAGR 1 2 EPKPEIYPCPSCCLAFSSQKFLSQHVERNHSSQNFPGPSARKLLQSENPCPGDQNQEQQYSDPSSCNDKTKGQEIKERSKLLNKRTWQREILRAFTSPPKGQMGSSRVGERMMEEEFRTGQKANPGNTGKLFVGVEISRIAK VKYGECGQGFSGKSDVITHQRTHTEGKP YVCRGCGRRFSQKSSLLRHQRTHTGEKP* >PRDM7_papHam Papio hamadryas (baboon) GAS* end of scaffold 0 MSPERSQEESPEEDTERTEWKPM 0 0 VKDAFKDISIYFTKEEWAEMGDWEKTRYRNVKRNYNALITI 1 2 GLRATRPAFMCHRRQAIKLQVDDTEDSDEEWTPRQQ 1 2 VKPPWMAVRVEQSKHQK 0 0 GMPKASFNNESSLKEVSGMANLLNTSGSEQAQKPVSPPGEARTSGQHSRLKL 1 2 ELRRKETEGKMYSLRERKGHAYKEVSEPQDDDYL 1 2 YCEMCQNFFIDSCAAHGPPTFIKDSAVEKGHPNRSALSLPPGLRIGPSGIPQAGLGVWNEASDLPLGLHFGPYEGRITQDEEAANNGYSWL 0 0 ITKGRNCYEYVDGKDKSWANWMR 2 1 YVNCARDDEEQNLVAFQYHRQIFYRTCRVIRPGCELLVWYGDEYGQELGIKWGSKWKKELMAGR 1 2 EPKPEIHPCPSCCLAFSSQKFLSQHVERNHSTQNFPGPSARRLLQPENLCSGDQNQEQQYSDPCSCNDKTKGQEIKERSKLLNKRTWQKEISRAFSSPPKGQMGSSRVGERMMEEESRTGQKVNPENIGKLFVEVGISRIAK VKYGECGQGFSDKSDVVIHQRTHTREKP YLCRECGRGFSQKSNLLRHQRTHTGEKP YLCRECGRGFRDNSSLRCHQRTHTGEKP YLCRECGRGFRDNSSLRCHQRTHTGEKP YLCRECGRGFSDNSSLRYHQRTHTGEKP YLCRECGRGFRDNSSLRYHQRTHTGEKP YLCRECGRGFSVKSNLLSHQRTHTGEKP YVCRECGRGFSDNSSLRCHQRTHTGEKP YLCRECGRGFSQMSHLRCHQRTHTGEKP YLCRECGRGFSVKSNLLSHQRTHTGEKP YVCRECGRGFSRKANLLSHQRTHTGEKP* 0 >PRDM7_micMur Microcebus murinus (lemur) ABDC01433247 0 MSPEKSQEESPEEDTERTERKPM 0 0 vKDAFKDISIYFTKEEWAEMGDWEKTRYRNVKRNYNALITI 1 2 GLRATRPAFMCHRRQAIKLQVDDTEDSDEEWTPRQQ 1 2 VKPPWMALRVEQRKHQK 0 0 GMPKASFSNESSLKELSRTANLLNASGSEQAQKPVSPSGEASTSGQHSRLKL 1 2 ELRKKETERKMYSLRERKGHAYKEVSEPQDDDYL 1 2 YCEKCQNFFIDSCAAHGPPTFVKDSAVDKGHPNRSALSLPPGLKIRPSGIPQAGLGVWNEASELPLGLHFGPYEGQVTEDEEAANSGYSWL 0 0 ITKGRNCYEYVDGKDDSWANWMR 2 1 YVNCARDEEEQNLVAFQYHRQIFYRTCQVIRPGCELLVWYGDEYGQELGIKWGSKWKEELTIRQ 1 2 EPKPEIHPCPSCSLAFSSQKFLSQHVKHTHSSQISPRTSGRKHLQPENPCPGDQNQEQQHSDPHSCNDKAKDQEVKERPKPFHKKTQQRGISRAFSSPPKGKMGSCREGKRIMEEEPRTGQKVGPGDTDKLCAAGGISRISR VKYGDSGQSFSDKSNVIIHQRTHTGEKP YVCRECGRGFSQKSDLLKHQRTHTGEKP YVCRECGRGFSQKSHLLRHQRTHTGEKP YVCRECGRGFSQKSDLLIHQRTHTGEKP YVCRECGRGFSCKSHLLIHQRTHTGEKP YVCRECGRGFSCKSSLLIHQRTHTGEKP YVCRGVWGEALAESQTSSYTRGHTQGRSP VFAGRVSKSLALNYISTATGGHLLTSHLP TPALGGASKGSLLTLYISQECKETRNN* >PRDM7_otoGar Otolemur garnettii (galago) GAS8 0 MSPEKSQEESPEEDTERTERKPM 0 0 VKDAFKDISIYFTKEEWAEMGDWEKTRYRNVKRNYNALITI 1 2 GLRATRPAFMCHRRQAIKLQVDDTEDSDEEWTPRQQ 1 2 VKHPWMAFRMEQSKRQK 0 0 ILKKCMLSFNMHLKELSGPASLPNISGSEQHQKHMSSPREASTSGQHSGRKS 1 2 DLRIKEIEVRMYSLRERKGHAYKEVSEPQDDDYL 1 2 yCEKCQNFFIDNCAVHGPPTFVKDTAVEKGHPNRSVLSLPSGLGIRTSGIPQAGFGVWNEASDLQLGLHFGPYEGQVTEDEEAANSGYSWL 0 0 ITKGRNCYEYVDGKDESQGNWMR 2 1 YVNCARDEEEQNLVAFQYHRQIFYRTCRVIRPGCELLVWYGDEYGQELGIKWGSKWKKELTAGQ 1 2 EPKPEIHPCPSCSLAFSTQKFLSQHVERTHPSQISQGTSGRKNLRPQTPCPRDENQEQQHSDPNSRNDKTKGQEVKEMSKTSHKKTQQSRISRIFSCPPKGQMGSSREGERMIEEEPRPDQKVGPGDTEKFCVAIGISGIVK VKNRECVQSFSNKS NLRHQRTHTGEKP YMCRDCGRGFSHKSSLFRHQRTHTGEKP YVCRDCGRGFSLKANLLTHQRTHTGEKP YVCRDCGQGFSQKAHLLRHQRTHTGEKP YMCRDCGQGFSRKAYLLTHQRTHTGEKP YVCRDCGQGFSQKAHLLTHQRTHTGEKP YVCRDCGRGFSHKSSLFRHQRTHTGEKP YICRDCG* >PRDM7_bosTau Bos taurus (cattle) adjacent to GAS8 and in correct orientation; pseudogene missing C2H2. 0 MSPNRSPEESIEGDTGRTEWKPT 0 0 AKDAFKDISIYFCKEEWAQMG*WEKIRYRNVKRNYEALITL 1 >PRDM7_ailMel Ailuropoda melanoleuca (panda) GAS8 synteny no 9 0 MSLNTSPEETPERDSGRTGWKPT 0 0 AKDAFKDISIYFSKEEWTEMGDWEKIRYRNVKRNYEALITI 1 2 GLRAPRPAFMCHRRQAIKPQVDDTEDSDEEWTPRRQ 1 2 VRPSWVAFRMEQSKHQR 0 0 GIPRAPLRNESSLKELSETAKLLNTSGSELGQKPVSLPGEASTSGHDSLQKL 1 2 GFRRKDVEVKMYSLRERKSLAYQEVSEPQDDDYL 1 2 yCEKCQNFFIDSCAVHGPPTFVKDSAVDKGQPNRSALTLPPGLRIRPSGIPQAGLGVWNEASDLPLGLHFGPYEGQITEDEEAANSGYSWL 0 0 ITKGRNCYEYVDGKDNSWANWMR 2 1 YVNCARDEEEQNLVAFQYHRQIFYRTCRVIRPGCELLVWYGDEYGQELGIKWGSKWKSELAAGK 1 2 EPKPEIHPCPSCSLAFSSQKFLSQHLEHNHPSQILSRKSASEHFQQEDPCPGHQNQQQQQHSDPHRWNDKAKGQEVKERFKPLLKSIRQRRISRAFSSPCKGQTRSSTVCEGMVEEEPSAGQKLNPEETGKLFMGVGMSGIIR VKYRGCGRDFSDRSHQSGHQRRHQKKP SVCKKVKREFSHKSVLITHQRTHTGEKP YVCRECGRGFTQRSNLIRHQRTHTGEKP YVCRECGRGFTQRSNLIRHQRTHTGEKP YVCRECGRGFTQRSSLIRHQRTHTGEKP YVCRECGRGFTLRPNLIGHQRTHTEALP INYISTTKEQM* 0 >PRDM7_felCat fragment no GAS8 chrUn_ACBE01450406:1-11,793 0 MEPSPASESARGQPGGPGTTSPLRFPEQSAERGSRKARWKPT 0 0 AKDAFKDISIYFSKEEWTEMGDWEKIRYRNVKRNYEALMTI 1 2 gLRAPRPAFMCHRRQAIKPQVDVTEDSDEEWTPRQQ 1 2 VKPSWVASRVDQNKQHKV 0 0 GTHRVPLSKESSLKDFSETAKLLNTSGSEQGQKPVSLPGEASTSGHHSRRKL 1 2 frRRKEIGVKMYSLRERKGFAYQEVSEPQDDDYL 1 2 yCEKCQNFFIDSCAVHGPPTFVKDNAVGKGHPNRSALTLPPGLRIRPSSIPEAGLGVWNEASDLPLGTHFGPYEGQITEDEEAANSGYSWL 0 0 ITKGRNCYEYVDGKDNSWANWMR 2 >PRDM7_canFam pseudgene 2 VKPSWVAFRMEQSKHQK 0 2 yCEK*QTFFIDSCTVHGPPTFVKDSEVDKGQPNHSALTLPPGLRIRTSSIPQAGLGVWN*ASDLPLGLHFGPYKGQITEDEEAANSGYSCL 0 0 ITKGRNCYEYVDGKDKDNSWANWMR 2 1 YMNCARDDEEQS*WPFNITGR--YSTEPVEQPGHQASCELLVWYGDEYSQELGIKWGSKWKSELTAGK 1 2 EPNPEIHPCPSCSL AFSSQKFLSQHLEHNHPSQILPRISVREHFRPKDPCPGCQNQQQQQHSDPQRWNDRAKGQEGKERFKPLPKSIRQRRISRAFSTPCKGQTTCEGIVKEEPSAGSQKLNPEDTGKLFKGVGMTRIIR VKYRGCGRGFNDRSHLSRHQRTHTGENP YVCRECGRGFIHRTNLIIHQRTHTGEKP YVCRECGQALYRGQISAYIRGHTQGRSPM >PRDM7_equCab missing front exons, some frameshifts 2 VKPSWVAFRVEQSKQQK 0 2 SGTAKLLKTSSSEQVQKPVSPLGEASSSEQHSRRKLELRRKEVGVKMYSLRERKGHAYQEVSEPQDDDYL 1 2 yCENCQNFFIDSCAAHGPPIFVKDSAVDKGHPNRSALTLPLGLRIRPSGIPEAGLGVWNEASDLPLGLHFGPYEGQITEDEEAANSGYSWL 0 0 ITKGRNCYEYVDGKDISWANWMR 2 1 YVNCARDDEEQNLVAFQYHRQIFYRTCRVVRPGCELLVWYGDEYGQELGIKWGSKWKRELTAGR 1 2 EPKLEIHPCPSCSLAFSSQKFLSQHVERNHPSQILPGTSARNHLQPEDPSPGDQNQQQQHSDPHSWKDKAHSQEVKERSKPLLKKIRQRRIPRAFSYPPKGQMENFRMRERIMEEKPSIGRKVNPEDTGKLFLEMRMSRNVR VQYGGCGRGFNDRASLIKHQRTHTGEKP YVCRECEQGFTQKSSLIAHQRTHTGEKP YVCRECEQGFSEKSHLIRHQRTHTGEKP YVCRECE* >PRDM7_loxAfr (elephant) pseudogene adjacent to GAS8 in standard orientation many frameshifts 0 MSLNTSPEETPERDSGRTGWKPT 0 0 AKDAFRDIFIYFSKEGYVEMGEWEKLCYRNLKMNYKALVTT 1 2 GLRASHPAFTCHCMQAIKAQMDDTEDSNEEQTPRQ 1 2 VRPSWVAFRMEQSKHQR 0 0 GMLRVPRSNESSLKNLSGTSIMLSRAGSEQAQKLVLPPGKASTSDEHSRQKP 1 2 EHRRKGVEVKMYSF*ERKGLVYQEIS*PQDDDYL 1 2 YCEKCQNFFIDTCESHGVPTFVKNSTTDSGHPNHLALTPSSGLRTRPSSIPKAWLRLWNKAFELLLGLPFSPCEGQVIEDEAVDNSGYSWL 0 0 ITKGRNCYEYVDGKDNSWANWMR 2 1 YVNGTQDEKEQNLVFFQYHRQIFYQTCYAVWPGCQLLVWYRDECGQELGIKWDNRGKKEFe 1 2 EPKPEAHPCPSCPLAFSSEKFLSQHMKHNHPSQSSPETPERKHLQPEDPHPGHQNQQQQQHSDPHRWNDKAEGQQTGDRSKPMFENIRQEVTSRAFSSLPKGQMVCSREGNRMMETEPSPGLKVNPEVTGKLFLGVESSRIAK VKYRGCGRDFSDRSHQSGHQRRHQKKP SVCKKVKREFSHKSVLITHQRTHSGEKS YVCKESGRGFSAKSNLIRPRRTHTGEKP YVCGERG*GFSV*SGLIIHQRAHSPEKP YVCREGRRGFGDKSSFIKHQRATLGEKS YVCKESGRGFSAKSNLIRPRRKKCRHDTTPHPQL* 0 >PRDMx_danRer Danio rerio (zebrafish) Q6P2A1 transcript BC064665 pseudo-homologous 0 MSLSPDLPPSEEQNLEIQGSATNCYSVVIIEEQDDTFNDQPF 1 2 YCEMCQQHFIDQCETHGPPSFTCDSPAALGTPQRALLTLPQGLVIGRSSISHAGLGVFNQGQTVPLGMHFGPFDGEEISEEKALDSANSWV 0 0 ICRGNNQYSYIDAEKDTHSNWMK 2 1 FVVCSRSETEQNLVAFQQNGRILFRCCRPISPGQEFRVWYAEEYAQGLGAIWDKIWDNKCISQ 1 2 GSTEEQATQNCPCPFCHYSFPTLVYLHAHVKRTHPNEYAQFTQTHPLESEAHTPITEVEQCLVASDEALSTQTQPVTESPQEQISTQNGQPIHQTENSDEPDASDIYTAAGEISDEI HACVDCGRSFLRSCHLKRHQRTIHSKEKP YCCSQCKKCFSQATGLKRHQHTH QEQEKNIESPDRPSDI YPCTKCTLSFVAKINLHQHLKRH HHGEYLRLVESGSLTAETEEDHT EVCFDKQDPNYEPPSRGRKSTKNSLKG RGCPKKVAVGRPRGRPPKNKNLEVEVQKIS PICTNCEQSFSDLETLKTHQCPRRDDEGDNVEHPQEASQ YICGECIRAFSNLDLLKAHECIQQGEGS YCCPHCDLYFNRMCNLRRHERTIHSKEKP YCCTVCLKSFTQSSGLKRHQQSHLRRKSHRQSSALFTAAIFPCAYCPFSFTDERYLYKHIRRHHPEMSLKYLSFQEGGVLSVEKP HSCSQCCKSFSTIKGFKNHSCFKQGEKV YLCPDCGKAFSWFNSLKQHQRIHTGEKP YTCSQCGKSFVHSGQLNVHLRTHTGEKP FLCSQCGESFRQSGDLRRHEQKHSGV RPCQCPDCGKSFSRPQSLKAHQQLHVGTKL FPCTQCGKSFTRRYHLTRHHQKMHS* 0 >ZNF133_homSap Homo sapiens (human) NP_001076799 KRAB Krueppel-associated box and zinc fingers 0 MAFRDVAVDFTQDEWRLLSPAQRTLYREVMLENYSNLVSL 1 2 GISFSKPELITQLEQGKETWREEKKCSPATCP 1 2 DPEPELYLDPFCPPGFSSQKFPMQHVLCNHPPWIFTCLCAEGNIQPGDPGPGDQ EKQQQASEGRPWSDQAEGPE GEGAMPLFGRTKKRTLG AFSRPPQRQPVSSRNGLRGVELEASPAQTGNPEETDKLLKRIEVLGFGT VNCGECGLSFSKMTNLLSHQRIHSGEKP YVCGVCEKGFSLKKSLARHQKAHSGEKP IVCRECGRGFNRKSTLIIHERTHSGEKP YMCSECGRGFSQKSNLIIHQRTHSGEKP YVCRECGKGFSQKSAVVRHQRTHLEEKT IVCSDCGLGFSDRSNLISHQRTHSGEKP YACKECGRCFRQRTTLVNHQRTHSKEKP YVCGVCGHSFSQNSTLISHRRTHTGEKP YVCGVCGRGFSLKSHLNRHQNIHSGEKP IVCKDCGRGFSQQSNLIRHQRTHSGEKP MVCGECGRGFSQKSNLVAHQRTHSGERP YVCRECGRGFSHQAGLIRHKRKHSREKP YMCRQCGLGFGNKSALITHKRAHSEEKP CVCRECGQGFLQKSHLTLHQMTHTGEKP YVCKTCGRGFSLKSHLSRHRKTTSVHHR LPVQPDPEPCAGQPSDSLYSL* 0 >ZNF343_homSap Homo sapiens (human) KRAB Krueppel-associated box and zinc fingers 0 MMLPYPSALGDQYWEEILLPKNGENVETMKKLTQNHKAK 1 2 GLPSNDTDCPQKKEGKAQIV 0 0 VPVTFRDVTVIFTEAEWKRLSPEQRNLYKEVMLENYRNLLSL 1 2 AEPKPEIYTCSSCLLAFSCQQFLSQHVLQIFLGLCAENHFHPGNSSPGHWKQQGQQYSHVSCWFENAEGQERGGGSKPWSARTEERETSRAFPSPLQRQSASPRKGNMVVETEPSSAQRPNPVQLDKGLKELETLRFGA INCREYEPDHNLESNFITNPRTLLGKKP YICSDCGRSFKDRSTLIRHHRIHSMEKP YVCSECGRGFSQKSNLSRHQRTHSEEKP YLCRECGQSFRSKSILNRHQWTHSEEKP YVCSECGRGFSEKSSFIRHQRTHSGEKP YVCLECGRSFCDKSTLRKHQRIHSGEKP YVCRECGRGFSQNSDLIKHQRTHLDEKP YVCRECGRGFCDKSTLIIHERTHSGEKP YVCGECGRGFSRKSLLLVHQRTHSGEKH YVCRECRRGFSQKSNLIRHQRTHSNEKP YICRECGRGFCDKSTLIVHERTHSGEKP YVCSECGRGFSRKSLLLVHQRTHSGEKH YVCRECGRGFSHKSNLIRHQRTH* 0 >ZNF169_homSap Homo sapiens (human) KRAB Krueppel-associated box and zinc fingers 0 MSPGLLTTRKEALMAFRDVAVAFTQKEWKLLSSAQRTLYREVMLENYSHLVSL 1 2 GIAFSKPKLIEQLEQGDEPWREENEHLLDLCP 1 2 EPRTEFQPSFPHLVAFSSSQLLRQYALSGHPTQIFPSSSAGGDFQLEAPRCSSEKGESGETEGPDSSLRKRPSRISRTFFSPHQGDPVEWVEGNREGGTDLRLAQRMSLGGSDTMLKGADTSESGAVIRGNYRLGLSKKSSLFSHQKH HVCPECGRGFCQRSDLIKHQRTHTGEKP YLCPECGRRFSQKASLSIHQRKHSGEKP YVCRECGRHFRYTSSLTNHKRIHSGERP FVCQECGRGFRQKIALLLHQRTHLEEKP FVCPECGRGFCQKASLLQHQSSHTGERP FLCLECGRSFRQQSLLLSHQVTHSGEKP YVCAECGHSFRQKVTLIRHQRTHTGEKP YLCPQCGRGFSQKVTLIGHQRTHTGEKP YLCPDCGRGFGQKVTLIRHQRTHTGEKP YLCPKCGRAFGFKSLLTRHQRTHSEEEL YVDRVCGQGLGQKSHLISDQRTHSGEKP CICDECGRGFGFKSALIRHQRTHSGEKP YVCRECGRGFSQKSHLHRHRRTKSGHQL LPQEVF* 0 >ZNF596_homSap Homo sapiens (human) KRAB Krueppel-associated box and zinc fingers 0 MESQESVTFQDVAVDFTQEEWALLDTSQRTLFREVMLENISHLVSV 1 2 GNQLYKSDVISHLEQGEQLSREGLGFLQGQSPVISDREDDPKKQEMLSMQHICKKDAPLISAMQWSHTQEDPLECNNFREKFTEILPLTQYVIPQVGKKPFISQDVGKAISYLPSFNIQKQIHSRSKS YECHQRRNTFIQSSAHRQHNNTQTGEKT FECHVCRKAFSKSSNLRRHEMIHTGVKP HGCHLCGKSFTHCSDLRKHERIHTGEKL YGCHLCGKAFSKSYNLRRHEVIHTKEKP NECHLCGKAFAHCSDLRKHERTHFGEKP YGCHLCGKTFSKTSYLRQHERTHNGEKP YGCHLCGKAFTHCSHLRKHERTHTGEKP YECHLCGKAFTESSVLRRHERTHTGEKP YECHLCWKAFTDSSVLKRHERTHTGEKP YECHLCGKTFNHSSVLRRHERTHTGEKP YECNICGKAFNRSYNFRLHKRIHTGEKP YKCYLCGKAFSKYFNLRQHENSCYKGNK* 0 >HKR1_homSap Homo sapiens (human) KRAB Krueppel-associated box and zinc fingers 0 MRVNHTVSTMLPTCMVHRQTMSCSGAGGITAFVAFRDVAVYFTQEEWRLLSPAQRTLHREVMLETYNHLVSL 1 2 EIPSSKPKLIAQLERGEAPWREERKCPLDLCP 1 2 ESKPEIQLSPSCPLIFSSQQALSQHVWLSHLSQLFSSLWAGNPLHLGKHYPEDQ KQQQDPFCFSGKAEWIQE GEDSRLLFGRVSKNGTSKALSSPPEEQQPAQSKEDNTVVDIGSSPERRADLEETDKVLHGLEVSGFGE IKYEEFGPGFIKESNLLSLQKTQTGETP YMYTEWGDSFGSMSVLIKNPRTHSGGKP YVCRECGRGFTWKSNLITHQRTHSGEKP YVCKDCGRGFTWKSNLFTHQRTHSGLKP YVCKECGQSFSLKSNLITHQRAHTGEKP YVCRECGRGFRQHSHLVRHKRTHSGEKP YICRECEQGFSQKSHLIRHLRTHTGEKP YVCTECGRHFSWKSNLKTHQRTHSGVKP YVCLECGQCFSLKSNLNKHQRSHTGEKP FVCTECGRGFTRKSTLSTHQRTHSGEKP FVCAECGRGFNDKSTLISHQRTHSGEKP FMCRECGRRFRQKPNLFRHKRAHSGA FVCRECGQGFCAKLTLIKHQRAHAGGKP HVCRECGQGFSRQSHLIRHQRTHSGEKP YICRKCGRGFSRKSNLIRHQRTHSG* 0 >PRDM11_homSap Homo sapiens (human) 511 aa 7 exons chr11:45115564 44% id PRDM9 SET 0 MLKMAEPIASLMIVECRACLRCSPLFLYQREK 0 0 DRMTENMKECLAQTNAAVGDMVTVVKTEVCSPLRDQEYGQPC 2 1 SRRPDSSAMEVEPKKLKGKRDLIVPKSFQQVDFW 1 2 FCESCQEYFVDECPNHGPPVFVSDTPVPVGIPDRAALTIPQGMEVVKDTSGESDVRCVNEVIPKGHIFGPYEGQISTQDKSAGFFSWL 0 0 IVDKNNRYKSIDGSDETKANWMR 2 1 YVVISREEREQNLLAFQHSERIYFRACRDIRPGEWLRVWYSEDYMKRLHSMSQETIHRNLAR 1 2 GEKRLQREKSEQVLDNPEDLRGPIHLSVLRQGKSPYKRGFDEGDVHPQAKKKKIDLIFKDVLEASLESAKVEAHQLALSTSLVIRKVPKYQDDAYSQCATTMTHGVQNIGQTQG EGDWKVPQGVSKEPGQLEDEEEEPSSFKADSPAEASLASDPHELPTTSFCPNCIRLKKKVRELQAELDMLKSGKLPEPPVLPPQVLELPEFSDPAGKLVWMRLLSEGRVRSGLCGG* 0 >PRDM1_homSap Homo sapiens (human) 825 aa 7 exons chr6 106,546,004 3DAL:KMDM..NLTQ SET + 5 C2H2 0 MLDICLEKRVGTTL 0 0 AAPKCNSSTVRFQGLAEGTKGTMKMDMEDADMTLWTEAEFEEKCTYIVNDHPWDSGADGGTSVQAEASLPRNLLFKYATNSEE 0 0 VIGVMSKEYIPKGTRFGPLIGEIYTNDTVPKNANRKYFWR 0 0 IYSRGELHHFIDGFNEEKSNWMRYVNPAHSPREQNLAACQNGMNIYFYTIKPIPANQELLVWYCRDFAERLHYPYPGELTMMNL 1 2 TQTQSSLKQPSTEKNELCPKNVPKREYSVKEILKLDSNPSKGKDLYRSNISPLTSEKDLDDFRRRGSPEMPFYPRVVYPIRAPLPEDFLKASLAYGIERPTYITRSPIPSSTTPSPSARSS PDQSLKSSSPHSSPGNTVSPVGPGSQEHRDSYAYLNASYGTEGLGSYPGYAPLPHLPPAFIPSYNAHYPKFLLPPYGMNCNGLSAVSSMNGINNFGLFPRLCPVYSNLLGGGSLPHPMLNPTS LPSSLPSDGARRLLQPEHPREVLVPAPHSAFSFTGAAASMKDKACSPTSGSPTAGTAATAEHVVQPKATSAAMAAPSSDEAMNLIKNKRNMTGYKTLPYPLKKQNGKIKYECNVCAKTFGQLSNLK 0 0 VHLRVHSGERPFKCQTCNKGFTQLAHLQKHYLVHTGEKPHECQ 0 0 VCHKRFSSTSNLKTHLRLHSGEKPYQCKVCPAKFTQFVHLKLHKRLHTRERPHKCSQCHKNYIHLCSLKVHLKGNCAAAPAPGLPLEDLTRINEEIEKFDISD NADRLEDVEDDISVISVVEKEILAVVRKEKEETGLKVSLQRNMGNGLLSSGCSLYESSDLPLMKLPPSNPLPLVPVKVKQETVEPMDP* >PRDM4_homSap Homo sapiens (human) 801 aa 11 exons chr12:108126644 3DB5:EHGPV..IGVPE SET + 1 + 6 C2H2 domaians 0 MHHR 2 1 MNEMNLSPVGMEQLTSSSVSNALPVSGSHLGLAASPTHSAIPAP 1 2 GLPVAIPNLGPSLSSLPSALSLMLPMGIGDRGVMCGLPERNYTLPPPPYPHLESSYFRTILP 1 2 GILSYLADRPPPQYIHPNSINVDGNTALSITNNPSALDPYQSNGNVGLEPGIVSIDSRSVNTHGAQSLHPSDGHEVALDTAITMENVSRVTSPISTDGMAEELTMDGVAGEHSQIPNGSRSHEPLSVDSVSN NLAADAVGHGGVIPMHGNGLELPVVMETDHIASRVNGMSDSALSDSIHTVAMSTNSVSVALSTSHNLASLESVSLHEVGLSLEPVAVSSITQEVAMGTGHVDVSSDSLSFVSPSLQMEDSNSNKENMATLFTI 1 2 WCTLCDRAYPSDCPEHGPVTFVPDTPIESRARLSLPKQLVLRQSIVGAEV 1 2 GVWTGETIPVRTCFGPLIGQQSHSMEVAEWTDKAVNHIWK 0 0 IYHNGVLEFCIITTDENECNWMMFVRKAR 2 1 NREEQNLVAYPHDGKIFFCTSQDIPPENELLFYYSRDYAQQI 1 2 GVPEHPDVHLCNCGKECNSYTEFKAHLTSHIHNHLPTQGHSGSHGPSHSKERKWKCSMCPQAFISPSKLHVHFMGHMGMKPHKCDFCSKAFSDPSNLRTHLKIHT 1 2 GQKNYRCTLCDKSFTQKAHLESHMVIHTGEKNLKCDYCDKLFMRRQDLKQHVLIHTQ 2 1 ERQIKCPKCDKLFLRTNHLKKHLNSHEGKRDYVCEKCTKAYLTKYHLTRHLKTCKGPTSSSSAPEEEEEDDSEEEDLADSVGTEDCRINSAVYSADESLSAHK* 0 >GAS8_homSap Homo sapiens (human) synteny marker right centromeric positive strand C16orf3- in second intron growth arrest-specific del cancer MAPKKKGKKGKAKGTPIVDGLAPEDMSKEQVEEHVSRIREELDREREERNYFQLERDKIHTFWEITRRQLEEKKAELRNKDREMEEAEERHQVEIKVYKQKVKHLLYEHQNNLTEMKAEG TVVMKLAQKEHRIQESVLRKDMRALKVELKEQELASEVVVKNLRLKHTEEITRMRNDFERQVREIEAKYDKKMKMLRDELDLRRKTELHEVEERKNGQIHTLMQRHEEAFTDIKNYYNDI TLNNLALINSLKEQMEDMRKKEDHLEREMAEVSGQNKRLADPLQKAREEMSEMQKQLANYERDKQILLCTKARLKVREKELKDLQWEHEVLEQRFTKVQQERDELYRKFTAAIQEVQQKT GFKNLVLERKLQALSAAVEKKEVQFNEVLAASNLDPAALTLVSRKLEDVLESKNSTIKDLQYELAQVCKAHNDLLRTYEAKLLAFGIPLDNVGFKPLETAVIGQTLGQGPAGLVGTPT* >CDH12_homSap Homo sapiens (human) synteny marker chr 5 794 aa MLTRNCLSLLLWVLFDGGLLTPLQPQPQQTLATEPRENVIHLPGQRSHFQRVKRGWVWNQFFVLEEYVGSEPQYVGKLHSDLDKGEGTVKYTLSGDGAGTVFTIDETTGDIHAIRSLDRE EKPFYTLRAQAVDIETRKPLEPESEFIIKVQDINDNEPKFLDGPYVATVPEMSPVGAYVLQVKATDADDPTYGNSARVVYSILQGQPYFSIDPKTGVIRTALPNMDREVKEQYQVLIQAK DMGGQLGGLAGTTIVNITLTDVNDNPPRFPKSIFHLKVPESSPIGSAIGRIRAVDPDFGQNAEIEYNIVPGDGGNLFDIVTDEDTQEGVIKLKKPLDFETKKAYTFKVEASNLHLDHRFH SAGPFKDTATVKISVLDVDEPPVFSKPLYTMEVYEDTPVGTIIGAVTAQDLDVGSSAVRYFIDWKSDGDSYFTIDGNEGTIATNELLDRESTAQYNFSIIASKVSNPLLTSKVNILINVL DVNEFPPEISVPYETAVCENAKPGQIIQIVSAADRDLSPAGQQFSFRLSPEAAIKPNFTVRDFRNNTAGIETRRNGYSRRQQELYFLPVVIEDSSYPVQSSTNTMTIRVCRCDSDGTILS CNVEAIFLPVGLSTGALIAILLCIVILLAIVVLYVALRRQKKKDTLMTSKEDIRDNVIHYDDEGGGEEDTQAFDIGALRNPKVIEENKIRRDIKPDSLCLPRQRPPMEDNTDIRDFIHQR LQENDVDPTAPPYDSLATYAYEGSGSVAESLSSIDSLTTEADQDYDYLTDWGPRFKVLADMFGEEESYNPDKVT*