{"refrec":{"BRefID":45256,"RR":"Journal of Molecular Evolution. Springer-Verlag: New York.  ISSN 0022-2844; e-ISSN 1432-1432","BEntID":42728,"PublicFlag":1,"CheckedFlag":0,"wosflag":1,"vabbflag":null,"RefStringPartII":". Springer-Verlag: New York.  ISSN 0022-2844; e-ISSN 1432-1432","DocTypID":16,"DocType":"Journal","MarineFlag":0,"FreshFlag":0,"BrackishFlag":0,"TerrestrialFlag":0,"Authorstring":null,"OrigTitleTranslFlag":0,"Authorstringtrunc":null,"Englishabstract":null,"AbstractOtherLang":null,"BibLvlCode":"S","StandardTitle":"Journal of Molecular Evolution","OrigTitleLangCode":"en","OrigTitleLangCodeExtended":"eng","OrigTitleLangID":15,"DateLastModified":{"date":"2024-12-10 01:33:17.368041","timezone_type":1,"timezone":"+01:00"},"UserAccessRight":null,"UserAccID":null,"AuthorKeywords":null,"OtherDescriptors":null,"Notes":null,"AnaPub":null,"MonPub":null,"DateUpdate":"2015-07-13","DateCreate":"2001-03-21","SecASFANote":null,"ConfID":null,"PeerRev":1,"VlizCoreFlag":1,"WoScode":null,"VABBcode":null,"OpenAcc":0},"refs":null,"anarec":null,"monrec":null,"serrec":{"SerID":45256,"ISSN":"0022-2844","Abbreviation":"J. Mol. Evol.","PublID":1622,"City":"New York","InpCentreCode":null,"ASFACode":null,"AntilopeFlag":0,"PerioID":null,"CurrentFlag":0,"PeerRevFlag":1,"DigISSN":"1432-1432","InputCentre":null,"Periodicity":null,"FromYear":1971,"ToYear":null,"WoSFlag":1,"ISSNL":"0022-2844","EmbargoYears":null,"VABBFlag":0},"relations":null,"relationsRev":null,"addrec":null,"othpubs":null,"ownerships":null,"authors":null,"mapdetails":null,"datasets":null,"monographs":null,"monparts":null,"serparts":[{"BRefID":205000,"RR":"<b>Mackey, L.Y.; Winnepenninckx, B.; De Wachter, R.; Backeljau, T.; Emschermann, P.; Garey, J.R.</b> (1996). 18S rRNA suggests that Entoprocta are protostomes, unrelated to Ectoprocta. <i>J. Mol. Evol. 42</i>: 552-559. <a href=\"http://hdl.handle.net/10067/157710151162165141\" target=\"_blank\">hdl.handle.net/10067/157710151162165141</a>","StandardTitle":"18S rRNA suggests that Entoprocta are protostomes, unrelated to Ectoprocta","AuthorsString":"Mackey, L.Y. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":261864,"RR":"<b>Van der Auwera, G.; De Wachter, R.</b> (1997). Complete large subunit ribosomal RNA sequences from the heterokont algae <i>Ochromonas danica, Nannochloropsis salina</i>, and <i>Tribonema aequale</i>, and phylogenetic analysis. <i>J. Mol. Evol. 45(1)</i>: 84-90. <a href=\"https://dx.doi.org/10.1007/PL00006205\" target=\"_blank\">https://dx.doi.org/10.1007/PL00006205</a>","StandardTitle":"Complete large subunit ribosomal RNA sequences from the heterokont algae <i>Ochromonas danica, Nannochloropsis salina</i>, and <i>Tribonema aequale</i>, and phylogenetic analysis","AuthorsString":"Van der Auwera, G.; De Wachter, R.","BibLvlCode":"AS"},{"BRefID":280885,"RR":"<b>Richelle-Maurer, E.; Boury-Esnault, N.; Itskovich, V.B.; Manuel, M.; Pomponi, S.A.; Van de Vyver, G.; Borchiellini, C.</b> (2006). Conservation and phylogeny of a novel family of non-<i>Hox</i> genes of the <i>Antp</i> class in Demospongiae (Porifera). <i>J. Mol. Evol. 63(2)</i>: 222-230. <a href=\"https://dx.doi.org/10.1007/s00239-005-0294-x\" target=\"_blank\">https://dx.doi.org/10.1007/s00239-005-0294-x</a>","StandardTitle":"Conservation and phylogeny of a novel family of non-<i>Hox</i> genes of the <i>Antp</i> class in Demospongiae (Porifera)","AuthorsString":"Richelle-Maurer, E. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":130942,"RR":"<b>Duda, T.F.</b> (2008). Differentiation of venoms of predatory marine gastropods: divergence of orthologous toxin genes of closely related <i>Conus</i> species with different dietary specializations. <i>J. Mol. Evol. 67(3)</i>: 315-321. <a href=\"http://dx.doi.org/10.1007/s00239-008-9155-8\" target=\"_blank\">http://dx.doi.org/10.1007/s00239-008-9155-8</a>","StandardTitle":"Differentiation of venoms of predatory marine gastropods: divergence of orthologous toxin genes of closely related <i>Conus</i> species with different dietary specializations","AuthorsString":"Duda, T.F.","BibLvlCode":"AS"},{"BRefID":292709,"RR":"<b>Loeza-Quintana, T.; Adamowicz, S.J.</b> (2018). Iterative calibration: a novel approach for calibrating the molecular clock using complex geological events. <i>J. Mol. Evol. 86(2)</i>: 118-137. <a href=\"https://dx.doi.org/10.1007/s00239-018-9831-2\" target=\"_blank\">https://dx.doi.org/10.1007/s00239-018-9831-2</a>","StandardTitle":"Iterative calibration: a novel approach for calibrating the molecular clock using complex geological events","AuthorsString":"Loeza-Quintana, T.; Adamowicz, S.J.","BibLvlCode":"AS"},{"BRefID":29944,"RR":"<b>Winnepenninckx, B.M.H.; Reid, D.G.; Backeljau, T.</b> (1998). Performance of 18S rRNA in littorinid Phylogeny (Gastropoda : Caenogastropoda). <i>J. Mol. Evol. 47(5)</i>: 586-596","StandardTitle":"Performance of 18S rRNA in littorinid Phylogeny (Gastropoda : Caenogastropoda)","AuthorsString":"Winnepenninckx, B.M.H. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":317061,"RR":"<b>Mes, T.H.M.; van Putten, J.P.M.</b> (2007). Positively selected codons in immune-exposed loops of the vaccine candidate OMP-P1 of <i>Haemophilus influenzae</i>. <i>J. Mol. Evol. 64(4)</i>: 411-422. <a href=\"https://dx.doi.org/10.1007/s00239-006-0021-2\" target=\"_blank\">https://dx.doi.org/10.1007/s00239-006-0021-2</a>","StandardTitle":"Positively selected codons in immune-exposed loops of the vaccine candidate OMP-P1 of <i>Haemophilus influenzae</i>","AuthorsString":"Mes, T.H.M.; van Putten, J.P.M.","BibLvlCode":"AS"},{"BRefID":248858,"RR":"<b>Lee, W.-J.; Conroy, J.; Howell, W.H.; Kocher, Th.D.</b> (1995). Structure and evolution of teleost mitochondrial control regions. <i>J. Mol. Evol. 41(1)</i>: 54-66. <a href=\"http://dx.doi.org/10.1007/BF00174041\" target=\"_blank\">http://dx.doi.org/10.1007/BF00174041</a>","StandardTitle":"Structure and evolution of teleost mitochondrial control regions","AuthorsString":"Lee, W.-J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":280791,"RR":"<b>Fry, B.G.; Roelants, K.; Norman, J.A.</b> (2009). Tentacles of venom: toxic protein convergence in the kingdom Animalia. <i>J. Mol. Evol. 68(4)</i>: 311-321. <a href=\"https://dx.doi.org/10.1007/s00239-009-9223-8\" target=\"_blank\">https://dx.doi.org/10.1007/s00239-009-9223-8</a>","StandardTitle":"Tentacles of venom: toxic protein convergence in the kingdom Animalia","AuthorsString":"Fry, B.G.; Roelants, K.; Norman, J.A.","BibLvlCode":"AS"},{"BRefID":348098,"RR":"<b>Schäfer, G.G.; Grebe, L.J.; Schinkel, R.; Lieb, B.</b> (2021). The evolution of hemocyanin genes in caenogastropoda: gene duplications and intron accumulation in highly diverse gastropods. <i>J. Mol. Evol. 89(9-10)</i>: 639-655. <a href=\"https://dx.doi.org/10.1007/s00239-021-10036-y\" target=\"_blank\">https://dx.doi.org/10.1007/s00239-021-10036-y</a>","StandardTitle":"The evolution of hemocyanin genes in caenogastropoda: gene duplications and intron accumulation in highly diverse gastropods","AuthorsString":"Schäfer, G.G. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":262073,"RR":"<b>Hendriks, L.; De Baere, R.; Van de Peer, Y.; Neefs, J.; Goris, A.; De Wachter, R.</b> (1991). The evolutionary position of the rhodophyte <i>Porphyra umbilicalis</i> and the basidiomycete <i>Leucosporidium scottii</i> among other eukaryotes as deduced from complete sequences of small ribosomal subunit RNA. <i>J. Mol. Evol. 32(2)</i>: 167-177. <a href=\"https://dx.doi.org/10.1007/BF02515389\" target=\"_blank\">https://dx.doi.org/10.1007/BF02515389</a>","StandardTitle":"The evolutionary position of the rhodophyte <i>Porphyra umbilicalis</i> and the basidiomycete <i>Leucosporidium scottii</i> among other eukaryotes as deduced from complete sequences of small ribosomal subunit RNA","AuthorsString":"Hendriks, L. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":296172,"RR":"<b>Robbens, S.; Rouzé, P.; Cock, J.M.; Spring, J.; Worden, A.Z.; Van de Peer, Y.</b> (2008). The FTO gene, implicated in human obesity, is found only in vertebrates and marine algae. <i>J. Mol. Evol. 66(1)</i>: 80-84. <a href=\"https://dx.doi.org/10.1007/s00239-007-9059-z\" target=\"_blank\">https://dx.doi.org/10.1007/s00239-007-9059-z</a>","StandardTitle":"The FTO gene, implicated in human obesity, is found only in vertebrates and marine algae","AuthorsString":"Robbens, S. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":6939,"RR":"<b>Smith, M.J.; Arndt, A.; Gorski, S.; Fajber, E.</b> (1993). The phylogeny of echinoderm classes based on mitochondrial gene arrangements. <i>J. Mol. Evol. 36</i>: 545-554","StandardTitle":"The phylogeny of echinoderm classes based on mitochondrial gene arrangements","AuthorsString":"Smith, M.J. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":261893,"RR":"<b>Saperas, N.; Buesa, C.; Abián, J.; Vandekerckhove, J.; Kasinsky, H.E.; Chival, M.</b> (1996). The primary structure of a chondrichthyan protamine: a new apparent contradiction in protamine evolution. <i>J. Mol. Evol. 43(5)</i>: 528-535. <a href=\"https://dx.doi.org/10.1007/PL00006113\" target=\"_blank\">https://dx.doi.org/10.1007/PL00006113</a>","StandardTitle":"The primary structure of a chondrichthyan protamine: a new apparent contradiction in protamine evolution","AuthorsString":"Saperas, N. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":304553,"RR":"<b>Ricci, M.; Peona, V.; Guichard, E.; Taccioli, C.; Boattini, A.</b> (2018). Transposable elements activity is positively related to rate of speciation in mammals. <i>J. Mol. Evol. 86(5)</i>: 303-310. <a href=\"https://dx.doi.org/10.1007/s00239-018-9847-7\" target=\"_blank\">https://dx.doi.org/10.1007/s00239-018-9847-7</a>","StandardTitle":"Transposable elements activity is positively related to rate of speciation in mammals","AuthorsString":"Ricci, M. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":280848,"RR":"<b>Robbens, S.; Petersen, J.; Brinkmann, H.; Rouzé, P.; Van de Peer, Y.</b> (2007). Unique regulation of the Calvin cycle in the ultrasmall green alga <i>Ostreococcus</i>. <i>J. Mol. Evol. 64(5)</i>: 601-604. <a href=\"https://dx.doi.org/10.1007/s00239-006-0159-y\" target=\"_blank\">https://dx.doi.org/10.1007/s00239-006-0159-y</a>","StandardTitle":"Unique regulation of the Calvin cycle in the ultrasmall green alga <i>Ostreococcus</i>","AuthorsString":"Robbens, S. <i>et al.</i>","BibLvlCode":"AS"},{"BRefID":253299,"RR":"<b>Piganeau, G.; Vandepoele, K.; Gourbière, S.; Van de Peer, Y.; Moreau, H.</b> (2009). Unravelling <i>cis</i>-regulatory elements in the genome of the smallest photosynthetic Eukaryote: phylogenetic footprinting in <i>Ostreococcus</i>. <i>J. Mol. Evol. 69(3)</i>: 249-259. <a href=\"https://dx.doi.org/10.1007/s00239-009-9271-0\" target=\"_blank\">https://dx.doi.org/10.1007/s00239-009-9271-0</a>","StandardTitle":"Unravelling <i>cis</i>-regulatory elements in the genome of the smallest photosynthetic Eukaryote: phylogenetic footprinting in <i>Ostreococcus</i>","AuthorsString":"Piganeau, G. <i>et al.</i>","BibLvlCode":"AS"}],"BEntOpen":null,"BEntPrivate":null,"availability":null,"litstyles":null,"thespers":null,"arch2discl":null,"SERpubls":null,"MONpubls":null,"pictures":[],"thestermsPath":null,"thestermsASFA":null,"taxtermsASFA":null,"geotermsASFA":null,"collections":null,"conf":null,"proj":null,"Physdatasets":null,"spcols":null,"doi":null,"publs":[{"PublID":1622,"PublName":"Springer-Verlag","InsID":null,"PersID":null,"INBOID":3958,"OrderNr":1}],"serparttypes":["A"],"monauthors":null,"MParts":null,"SParts":null,"hLibs":null,"langs":[{"BEntID":42728,"AbstractFlag":0,"LangID":15,"LangCode":"en","Lang":"English","DutchTerm":"Engels","LangCodeExtended":"eng"}],"urls":null,"thesterms":null,"taxterms":null,"geoterms":null,"othterms":null,"asfacodes":null,"asfa2codes":null,"thestermsFRIS":null,"taxtermsFRIS":null,"geotermsFRIS":null,"othtermsFRIS":null,"resmessage":"","complete":1,"sessions":{"newSesName":null,"newSesDate":{"date":"2001-03-21 18:02:36.793000","timezone_type":3,"timezone":"Europe/Brussels"},"updSesName":"Haspeslagh, Jan, J.","updSesDate":{"date":"2015-07-13 08:11:48.230000","timezone_type":3,"timezone":"Europe/Brussels"}}}