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<document id="6E1BF8A04FDBE01B8E191FC0111B5079" ID-DOI="10.11646/phytotaxa.365.1.1" ID-ISSN="1179-3163" IM.bibliography_approvedBy="felipe" IM.illustrations_approvedBy="felipe" IM.materialsCitations_approvedBy="felipe" IM.metadata_approvedBy="felipe" IM.tables_requiresApprovalFor="GgImagineBatch" IM.taxonomicNames_approvedBy="felipe" IM.treatments_approvedBy="felipe" checkinTime="1725584015738" checkinUser="felipe" docAuthor="Mai, Truc, Johansen, Jeffrey R., Pietrasiak, Nicole, Bohunická, Markéta &amp; Martin, Michael P." docDate="2018" docId="03BFDE646C4EFFA5009AFBC6FF4BFC8B" docLanguage="en" docName="phytotaxa.365.1.1.pdf" docOrigin="Phytotaxa 365 (1)" docSource="http://dx.doi.org/10.11646/phytotaxa.365.1.1" docStyle="DocumentStyle:96748F8F1B6C902996E134952A3A36B9.13:Phytotaxa.2014-.journal_article" docStyleId="96748F8F1B6C902996E134952A3A36B9" docStyleName="Phytotaxa.2014-.journal_article" docStyleVersion="13" docTitle="Drouetiella hepatica Mai, Johansen et Pietrasiak 2018, sp. nov." docType="treatment" docVersion="1" lastPageNumber="34" masterDocId="FF86A61C6C6EFF840012FFAAFF98FF96" masterDocTitle="Revision of the Synechococcales (Cyanobacteria) through recognition of four families including Oculatellaceae fam. nov. and Trichocoleaceae fam. nov. and six new genera containing 14 species" masterLastPageNumber="59" masterPageNumber="1" pageNumber="33" updateTime="1725594083510" updateUser="GgImagineBatch" zenodo-license-figures="UNSPECIFIED" zenodo-license-treatments="UNSPECIFIED">
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<mods:title id="880CF2F3FD573CB30420095AD4CC380F">Revision of the Synechococcales (Cyanobacteria) through recognition of four families including Oculatellaceae fam. nov. and Trichocoleaceae fam. nov. and six new genera containing 14 species</mods:title>
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<mods:namePart id="C1D5042AF56A8771CC881920EA190AD9">Mai, Truc</mods:namePart>
<mods:affiliation id="5FCAD93928760B905E92A5CA5CB27A27">Department of Biology, John Carroll University, 1 John Carroll Blvd., University Heights, Ohio 44118, USA &amp; Department of Plant and Environmental Sciences, New Mexico State University, Skeen Hall Room N 127, P. O Box 30003 MSC 3 Q, Las Cruces, New Mexico 88003, USA.</mods:affiliation>
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<mods:namePart id="93759FB536E34B6AB7FC4B5CA083B8CC">Johansen, Jeffrey R.</mods:namePart>
<mods:affiliation id="096A74617D8B5F7B42133E11D12BA263">Department of Biology, John Carroll University, 1 John Carroll Blvd., University Heights, Ohio 44118, USA &amp; Department of Botany, Faculty of Science, University of South Bohemia, 31 Branišovská, 37005 České Budějovice, Czech Republic</mods:affiliation>
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<mods:namePart id="9D8A8473E987B829B419BBF32F8AF014">Pietrasiak, Nicole</mods:namePart>
<mods:affiliation id="B7AB750B935E4AE861E99B4298E5F0FD">Department of Plant and Environmental Sciences, New Mexico State University, Skeen Hall Room N 127, P. O Box 30003 MSC 3 Q, Las Cruces, New Mexico 88003, USA.</mods:affiliation>
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<mods:namePart id="E208E98EB8E1369DDC6CC899A14E51A0">Bohunická, Markéta</mods:namePart>
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<mods:namePart id="BC2E5A2842ECF9CF5AFB572B62079428">Martin, Michael P.</mods:namePart>
<mods:affiliation id="3725DBD4E3DCE99B20F5F8C6A5026130">Department of Biology, John Carroll University, 1 John Carroll Blvd., University Heights, Ohio 44118, USA</mods:affiliation>
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<treatment id="03BFDE646C4EFFA5009AFBC6FF4BFC8B" LSID="urn:lsid:plazi:treatment:03BFDE646C4EFFA5009AFBC6FF4BFC8B" httpUri="http://treatment.plazi.org/id/03BFDE646C4EFFA5009AFBC6FF4BFC8B" lastPageId="33" lastPageNumber="34" pageId="32" pageNumber="33">
<subSubSection id="C30C3CF96C4EFFA4009AFBC6FCBAFB13" box="[136,802,1132,1157]" pageId="32" pageNumber="33" type="nomenclature">
<paragraph id="8BA96F726C4EFFA4009AFBC6FCBAFB13" blockId="32.[136,1452,1132,2093]" box="[136,802,1132,1157]" pageId="32" pageNumber="33">
<heading id="D0E1D81E6C4EFFA4009AFBC6FCBAFB13" bold="true" box="[136,802,1132,1157]" fontSize="11" level="1" pageId="32" pageNumber="33" reason="1">
<emphasis id="B962B3606C4EFFA4009AFBC6FCBAFB13" bold="true" box="[136,802,1132,1157]" pageId="32" pageNumber="33">
<taxonomicName id="4C1614F16C4EFFA4009AFBC6FD5CFB13" authority="Mai, Johansen et Pietrasiak" authorityName="Mai, Johansen et Pietrasiak" authorityYear="2018" box="[136,708,1132,1157]" class="Cyanobacteriia" family="Oculatellaceae" genus="Drouetiella" higherTaxonomySource="GBIF" kingdom="Bacteria" order="Synechococcales" pageId="32" pageNumber="33" phylum="Cyanobacteria" rank="species" species="hepatica" status="sp. nov.">
<emphasis id="B962B3606C4EFFA4009AFBC6FEECFB13" bold="true" box="[136,372,1132,1157]" italics="true" pageId="32" pageNumber="33">Drouetiella hepatica</emphasis>
Mai, Johansen 
<emphasis id="B962B3606C4EFFA40222FBC6FDDCFB13" bold="true" box="[560,580,1132,1157]" italics="true" pageId="32" pageNumber="33">et</emphasis>
Pietrasiak
</taxonomicName>
<emphasis id="B962B3606C4EFFA402D9FBC6FCBAFB13" bold="true" box="[715,802,1132,1157]" italics="true" pageId="32" pageNumber="33">
<taxonomicNameLabel id="A2510E1B6C4EFFA402D9FBC6FCBAFB13" box="[715,802,1132,1157]" pageId="32" pageNumber="33" rank="species">sp. nov.</taxonomicNameLabel>
</emphasis>
</emphasis>
</heading>
</paragraph>
</subSubSection>
<subSubSection id="C30C3CF96C4EFFA4009AFB3AFDA8FB5B" pageId="32" pageNumber="33" type="diagnosis">
<paragraph id="8BA96F726C4EFFA4009AFB3AFDA8FB5B" blockId="32.[136,1452,1132,2093]" pageId="32" pageNumber="33">
<emphasis id="B962B3606C4EFFA4009AFB3AFE9DFB3F" bold="true" box="[136,261,1168,1193]" pageId="32" pageNumber="33">Diagnosis:</emphasis>
―Distinguished from the other species of the genus by its meristematic zones and false branching, and by its wide variability in trichome width.
</paragraph>
</subSubSection>
<subSubSection id="C30C3CF96C4EFFA400AFFB72FB86F97F" pageId="32" pageNumber="33" type="description">
<paragraph id="8BA96F726C4EFFA400AFFB72FC2BFA7B" blockId="32.[136,1452,1132,2093]" pageId="32" pageNumber="33">
<emphasis id="B962B3606C4EFFA400AFFB72FEF5FB67" bold="true" box="[189,365,1240,1265]" pageId="32" pageNumber="33">Description:—</emphasis>
Colony brownish or purplish-brown, forming floating, mucilaginous mats in liquid culture. Filaments long or short. Mature filaments 2.8–3.7 μm wide (
<figureCitation id="132D73F76C4EFFA40345FB56FB9BFA83" box="[855,1027,1276,1301]" captionStart="FIGURE 16" captionStartId="30.[136,229,1897,1918]" captionTargetBox="[222,1365,187,1869]" captionTargetId="figure-16@30.[222,1365,187,1869]" captionTargetPageId="30" captionText="FIGURE 16. Drouetiella hepatica. A.Heterogeneity in trichome width between young and mature filaments, young filaments isodiametric to slightly cylindrical. B–C. False-branching very rare in young trichomes, only single false-branches observered. D–F. Sheath sometimes elongated and lamellate as in (E). G. Rapid cell division in meristematic zones sometimes caused twisted trichomes. H. Frequent necridia occur along actively dividing trichomes. Scale bar 10μm in 1000X magnification." pageId="32" pageNumber="33">Figs. 16a, g–h</figureCitation>
), young filaments narrower, 2.3–2.8 μm wide (
<figureCitation id="132D73F76C4EFFA400EDFA8AFE1FFAAF" box="[255,391,1312,1337]" captionStart="FIGURE 16" captionStartId="30.[136,229,1897,1918]" captionTargetBox="[222,1365,187,1869]" captionTargetId="figure-16@30.[222,1365,187,1869]" captionTargetPageId="30" captionText="FIGURE 16. Drouetiella hepatica. A.Heterogeneity in trichome width between young and mature filaments, young filaments isodiametric to slightly cylindrical. B–C. False-branching very rare in young trichomes, only single false-branches observered. D–F. Sheath sometimes elongated and lamellate as in (E). G. Rapid cell division in meristematic zones sometimes caused twisted trichomes. H. Frequent necridia occur along actively dividing trichomes. Scale bar 10μm in 1000X magnification." pageId="32" pageNumber="33">Figs. 16b–f</figureCitation>
), occasionally with false branching (
<figureCitation id="132D73F76C4EFFA4033FFA8AFC34FAAF" box="[813,940,1312,1337]" captionStart="FIGURE 16" captionStartId="30.[136,229,1897,1918]" captionTargetBox="[222,1365,187,1869]" captionTargetId="figure-16@30.[222,1365,187,1869]" captionTargetPageId="30" captionText="FIGURE 16. Drouetiella hepatica. A.Heterogeneity in trichome width between young and mature filaments, young filaments isodiametric to slightly cylindrical. B–C. False-branching very rare in young trichomes, only single false-branches observered. D–F. Sheath sometimes elongated and lamellate as in (E). G. Rapid cell division in meristematic zones sometimes caused twisted trichomes. H. Frequent necridia occur along actively dividing trichomes. Scale bar 10μm in 1000X magnification." pageId="32" pageNumber="33">Fig. 16a–b</figureCitation>
). Sheath firm, colorless, thin to occasionally enlarged (
<figureCitation id="132D73F76C4EFFA400E4FAEEFEE0FACB" box="[246,376,1348,1373]" captionStart="FIGURE 16" captionStartId="30.[136,229,1897,1918]" captionTargetBox="[222,1365,187,1869]" captionTargetId="figure-16@30.[222,1365,187,1869]" captionTargetPageId="30" captionText="FIGURE 16. Drouetiella hepatica. A.Heterogeneity in trichome width between young and mature filaments, young filaments isodiametric to slightly cylindrical. B–C. False-branching very rare in young trichomes, only single false-branches observered. D–F. Sheath sometimes elongated and lamellate as in (E). G. Rapid cell division in meristematic zones sometimes caused twisted trichomes. H. Frequent necridia occur along actively dividing trichomes. Scale bar 10μm in 1000X magnification." pageId="32" pageNumber="33">Figs. 16c–e</figureCitation>
) and lamellate (
<figureCitation id="132D73F76C4EFFA4023BFAEEFD1DFACB" box="[553,645,1348,1373]" captionStart="FIGURE 16" captionStartId="30.[136,229,1897,1918]" captionTargetBox="[222,1365,187,1869]" captionTargetId="figure-16@30.[222,1365,187,1869]" captionTargetPageId="30" captionText="FIGURE 16. Drouetiella hepatica. A.Heterogeneity in trichome width between young and mature filaments, young filaments isodiametric to slightly cylindrical. B–C. False-branching very rare in young trichomes, only single false-branches observered. D–F. Sheath sometimes elongated and lamellate as in (E). G. Rapid cell division in meristematic zones sometimes caused twisted trichomes. H. Frequent necridia occur along actively dividing trichomes. Scale bar 10μm in 1000X magnification." pageId="32" pageNumber="33">Fig. 16e</figureCitation>
<emphasis id="B962B3606C4EFFA40296FAEEFD15FACB" bold="true" box="[644,653,1348,1373]" pageId="32" pageNumber="33">)</emphasis>
, up to 4.4 μm wide. Trichomes not or slightly constricted at cross-walls, cylindrical, with compacted coils at meristematic zones (
<figureCitation id="132D73F76C4EFFA402E9FAC2FCE1FA17" box="[763,889,1384,1409]" captionStart="FIGURE 16" captionStartId="30.[136,229,1897,1918]" captionTargetBox="[222,1365,187,1869]" captionTargetId="figure-16@30.[222,1365,187,1869]" captionTargetPageId="30" captionText="FIGURE 16. Drouetiella hepatica. A.Heterogeneity in trichome width between young and mature filaments, young filaments isodiametric to slightly cylindrical. B–C. False-branching very rare in young trichomes, only single false-branches observered. D–F. Sheath sometimes elongated and lamellate as in (E). G. Rapid cell division in meristematic zones sometimes caused twisted trichomes. H. Frequent necridia occur along actively dividing trichomes. Scale bar 10μm in 1000X magnification." pageId="32" pageNumber="33">Figs. 16a,g</figureCitation>
), 1.5–2.1 μm wide in young trichomes and 1.7–3.0 μm wide in mature trichomes. Hormogonia absent. Cells longer than wide and occasionally elongated, (2.2) 3.1–4.5 μm long, or in meristematic regions isodiametric, 2.0–2.6 μm long, with one central granule present in both young and mature cells. Necridia present (
<figureCitation id="132D73F76C4EFFA401F4FA7EFDD0FA7B" box="[486,584,1492,1517]" captionStart="FIGURE 16" captionStartId="30.[136,229,1897,1918]" captionTargetBox="[222,1365,187,1869]" captionTargetId="figure-16@30.[222,1365,187,1869]" captionTargetPageId="30" captionText="FIGURE 16. Drouetiella hepatica. A.Heterogeneity in trichome width between young and mature filaments, young filaments isodiametric to slightly cylindrical. B–C. False-branching very rare in young trichomes, only single false-branches observered. D–F. Sheath sometimes elongated and lamellate as in (E). G. Rapid cell division in meristematic zones sometimes caused twisted trichomes. H. Frequent necridia occur along actively dividing trichomes. Scale bar 10μm in 1000X magnification." pageId="32" pageNumber="33">Fig. 16h</figureCitation>
). End cells cylindrical, rounded.
</paragraph>
<paragraph id="8BA96F726C4EFFA400AFFA52FB86F97F" blockId="32.[136,1452,1132,2093]" pageId="32" pageNumber="33">
D1-D1’ helix 64 nucleotides long, with 3’ unilateral bulge of 7 nucleotides (5’-CAUCCCA-3’). Mid-helix region with a mismatch at position 24/34–35 immediately separated from the terminal loop by a 5’-GC:GC-3’ clamp, and two mismatches at position 9 (C/U) and 21 (G/A) on the 5’ strand. Terminal loop having sequence 5’-AAUCA-3’ (
<figureCitation id="132D73F76C4EFFA40542F9EAFA07F9CF" box="[1360,1439,1600,1625]" captionStart="FIGURE 6" captionStartId="15.[136,229,1976,1997]" captionTargetBox="[157,1425,273,1857]" captionTargetId="figure-14@15.[151,1436,267,1882]" captionTargetPageId="15" captionText="FIGURE 6. D1-D1’ stems of species described in Oculatellaceae.The stem structures of genera described previously in other publications (Oculatella, Thermoleptolyngbya, Timaviella) or in publications under provision (Trichotorquatus) are not shown here." pageId="32" pageNumber="33">Fig. 6f</figureCitation>
). Box B helix 34 nucleotides long, with one basal internal loop at position 5/29–30 and one unpaired adenine residue at position 9 of the 5’ strand (
<figureCitation id="132D73F76C4EFFA401A5F922FD91F937" box="[439,521,1672,1697]" captionStart="FIGURE 7" captionStartId="17.[136,229,1928,1949]" captionTargetBox="[314,1274,759,1806]" captionTargetId="figure-238@17.[311,1276,751,1831]" captionTargetPageId="17" captionText="FIGURE 7. Box B helices of species described in Oculatellaceae. The structures of genera described previously in other publications (Oculatella, Thermoleptolyngbya, Timaviella) or in publications under provision (Trichotorquatus) are not shown here." pageId="32" pageNumber="33">Fig. 7e</figureCitation>
). V2 helix 21 nucleotides long, with terminal loop having sequence 5’-AAUAU-3’ (
<figureCitation id="132D73F76C4EFFA40082F906FF78F953" box="[144,224,1708,1733]" captionStart="FIGURE 8" captionStartId="18.[136,229,1187,1208]" captionTargetBox="[152,1434,425,1107]" captionTargetId="figure-143@18.[151,1436,422,1162]" captionTargetPageId="18" captionText="FIGURE 8. V2 helices of species described in Oculatellaceae. Several species do not have this structure, including Pegethrix convoluta, P. indistincta, Antartic Pegethrix species, Cartusia fontana¸ Kaiparowitsia implicata." pageId="32" pageNumber="33">Fig. 8c</figureCitation>
). V3 helix 51 nucleotides long, with one large internal loop at position 10–12/39–41 and one unpaired guanine residue at position 46 on 3’ strand. Terminal loop sequence 5’-UUAG-3’ (
<figureCitation id="132D73F76C4EFFA403D0F97AFB89F97F" box="[962,1041,1744,1769]" captionStart="FIGURE 9" captionStartId="19.[136,229,1958,1979]" captionTargetBox="[229,912,769,1871]" captionTargetId="figure-135@19.[151,1436,768,1875]" captionTargetPageId="19" captionText="FIGURE 9. V3 helices of species described in Oculatellaceae. All species described have this structure. The V3 helix of Cartusia aeruginosa is missing because we do not have the full length of its ITS region." pageId="32" pageNumber="33">Fig. 9f</figureCitation>
).
</paragraph>
</subSubSection>
<subSubSection id="C30C3CF96C4EFFA400AFF95EFEEDF8A7" pageId="32" pageNumber="33" type="etymology">
<paragraph id="8BA96F726C4EFFA400AFF95EFEEDF8A7" blockId="32.[136,1452,1132,2093]" pageId="32" pageNumber="33">
<emphasis id="B962B3606C4EFFA400AFF95EFEFCF89B" bold="true" box="[189,356,1780,1805]" pageId="32" pageNumber="33">Etymology:—</emphasis>
<emphasis id="B962B3606C4EFFA40176F95EFE57F89B" box="[356,463,1780,1805]" italics="true" pageId="32" pageNumber="33">hepaticus</emphasis>
(L.): of or pertaining to the liver, in reference to the dark reddish brown (liver-colored) color of the colonies.
</paragraph>
</subSubSection>
<subSubSection id="C30C3CF96C4EFFA500AFF896FF4BFC8B" lastPageId="33" lastPageNumber="34" pageId="32" pageNumber="33" type="materials_examined">
<paragraph id="8BA96F726C4EFFA400AFF896FD6AF8EF" blockId="32.[136,1452,1132,2093]" pageId="32" pageNumber="33">
<emphasis id="B962B3606C4EFFA400AFF896FEFBF8C3" bold="true" box="[189,355,1852,1877]" pageId="32" pageNumber="33">Type locality:</emphasis>
― 
<collectingCountry id="F3012FE26C4EFFA4016DF896FE7DF8C3" box="[383,485,1852,1877]" name="Slovakia" pageId="32" pageNumber="33">Slovakia</collectingCountry>
. National Park Slovak Paradise: Waterfall Kaskady, gorge Sucha Bela, collected in 2000 by Bohuslav Uher. Found on subaerial limestone.
</paragraph>
<paragraph id="8BA96F726C4EFFA400AFF82EFE8FF857" blockId="32.[136,1452,1132,2093]" pageId="32" pageNumber="33">
<materialsCitation id="3B7E652F6C4EFFA400AFF82EFE8FF857" collectionCode="BRY" collectorName="Monte L. Bean Museum" location="Utah" pageId="32" pageNumber="33" specimenCode="BRY37778" specimenCount="1" stateProvince="Utah" typeStatus="holotype">
<emphasis id="B962B3606C4EFFA400AFF82EFD8FF80B" bold="true" box="[189,535,1924,1949]" pageId="32" pageNumber="33">
<typeStatus id="54ADD1D06C4EFFA400AFF82EFEB2F80B" box="[189,298,1924,1949]" pageId="32" pageNumber="33" type="holotype">Holotype</typeStatus>
here designated:—
</emphasis>
<specimenCode id="DBB0C7096C4EFFA40204F82EFD05F80B" box="[534,669,1924,1949]" collectionCode="BRY" country="USA" httpUri="http://biocol.org/urn:lsid:biocol.org:col:15673" lsid="urn:lsid:biocol.org:col:15673" name="Brigham Young University - S.L. Welsh Herbarium" pageId="32" pageNumber="33" type="Herbarium">BRY37778</specimenCode>
!, Herbarium for Nonvascular Cryptogams, 
<collectorName id="26E30AA46C4EFFA40499F82EFA3FF80B" box="[1163,1447,1924,1949]" pageId="32" pageNumber="33">Monte L. Bean Museum</collectorName>
, Provo, 
<collectingRegion id="49D2A1906C4EFFA400CBF802FE8BF857" box="[217,275,1960,1985]" country="United States of America" name="Utah" pageId="32" pageNumber="33">Utah</collectingRegion>
.
</materialsCitation>
</paragraph>
<paragraph id="8BA96F726C4EFFA400AFF866FA08F873" blockId="32.[136,1452,1132,2093]" box="[189,1424,1996,2021]" pageId="32" pageNumber="33">
<emphasis id="B962B3606C4EFFA400AFF866FE13F873" bold="true" box="[189,395,1996,2021]" pageId="32" pageNumber="33">Reference strain:</emphasis>
― 
<collectionCode id="ED07F7B76C4EFFA401BCF866FE62F873" box="[430,506,1996,2021]" pageId="32" pageNumber="33">UHER</collectionCode>
2000/2452, Algal Culture Collection at John Carroll University, Cleveland, 
<collectingCountry id="F3012FE26C4EFFA40543F866FA15F873" box="[1361,1421,1996,2021]" name="United States of America" pageId="32" pageNumber="33">USA</collectingCountry>
.
</paragraph>
<paragraph id="8BA96F726C4EFFA500AFF85AFDBBFEFB" blockId="32.[136,1452,1132,2093]" lastBlockId="33.[136,1452,160,797]" lastPageId="33" lastPageNumber="34" pageId="32" pageNumber="33">
<emphasis id="B962B3606C4EFFA400AFF85AFE2AF79F" bold="true" box="[189,434,2032,2057]" pageId="32" pageNumber="33">Taxonomic notes:—</emphasis>
The characteristic coloration of the trichomes is similar to 
<taxonomicName id="4C1614F16C4EFFA4046CF85AFD73F7BB" authority="(Gomont 1899: 38) Umezaki &amp; Watanabe (1994: 203)" authorityName="Umezaki &amp; Watanabe" authorityPageNumber="203" authorityYear="1994" baseAuthorityName="Gomont" baseAuthorityPageNumber="38" baseAuthorityYear="1899" class="Cyanophyceae" family="Oscillatoriaceae" genus="Leptolyngbya" kingdom="Bacteria" order="Nostocales" pageId="32" pageNumber="33" phylum="Cyanobacteria" rank="species" species="cebennensis">
<emphasis id="B962B3606C4EFFA4046CF85AFA33F79F" box="[1150,1451,2032,2057]" italics="true" pageId="32" pageNumber="33">Leptolyngbya cebennensis</emphasis>
(
<bibRefCitation id="EF8712836C4EFFA40082F7BEFEC0F7BB" author="Gomont, M." box="[144,344,2068,2093]" pageId="32" pageNumber="33" pagination="25 - 41" refId="ref33078" refString="Gomont, M. (1899) Sur quelques Oscillariees nouvelles. Bulletin de la Societe Botanique de France 46: 25 - 41, 1 pl." type="journal article" year="1899">Gomont 1899: 38</bibRefCitation>
) 
<bibRefCitation id="EF8712836C4EFFA4017AF7BEFD73F7BB" author="Umezaki, I. &amp; Watanabe, M." box="[360,747,2068,2093]" pageId="32" pageNumber="33" pagination="175 - 219" refId="ref38017" refString="Umezaki, I. &amp; Watanabe, M. (1994) Enumeration of the Cyanophyta (blue-green algae) of Japan. 1. Chroococcales and Oscillatoriales. Japanese Journal of Phycology 42: 175 - 219." type="journal article" year="1994">Umezaki &amp; Watanabe (1994: 203)</bibRefCitation>
</taxonomicName>
, 
<taxonomicName id="4C1614F16C4EFFA502E5F7BEFE07FF2F" authority="(Kutzing ex Lemmermann 1910: 206) Anagnostidis &amp; Komarek (1988: 391)" authorityName="Anagnostidis &amp; Komarek" authorityPageNumber="391" authorityYear="1988" baseAuthorityName="Kutzing ex Lemmermann" baseAuthorityPageNumber="206" baseAuthorityYear="1910" class="Cyanophyceae" family="Oscillatoriaceae" genus="Leptolyngbya" kingdom="Bacteria" lastPageId="33" lastPageNumber="34" order="Nostocales" pageId="32" pageNumber="33" phylum="Cyanobacteria" rank="species" species="carnea">
<emphasis id="B962B3606C4EFFA402E5F7BEFCFAF7BB" box="[759,866,2068,2093]" italics="true" pageId="32" pageNumber="33">L. carnea</emphasis>
(Kützing 
<emphasis id="B962B3606C4EFFA403C6F7BEFC75F7BB" box="[980,1005,2068,2093]" italics="true" pageId="32" pageNumber="33">ex</emphasis>
<bibRefCitation id="EF8712836C4EFFA403E6F7BEFA93F7BB" author="Lemmermann, E." box="[1012,1291,2068,2093]" pageId="32" pageNumber="33" pagination="497 - 712" refId="ref34809" refString="Lemmermann, E. (1910) Algen I (Schizophyceen, Flagellaten, Peridineen), Dritter Band. In: Kryptogamenflora der Mark Brandenburg und angrenzender Gebiete Herausgegeben von dem Botanishcen Verein der Provinz Brandenburg. Verlag von Gebruder Borntraeger. Leipzig, pp. 497 - 712. https: // doi. org / 10.5962 / bhl. title. 4953" type="book chapter" year="1910">Lemmermann 1910: 206</bibRefCitation>
) Anagnostidis &amp; 
<bibRefCitation id="EF8712836C4FFFA500B5FF0AFE07FF2F" author="Komarek, J. &amp; Lukavsky, J." box="[167,415,160,185]" pageId="33" pageNumber="34" pagination="249 - 267" refId="ref34146" refString="Komarek, J. &amp; Lukavsky, J. (1988) Arthronema, a new cyanophyte genus from Afro-Asian deserts. Archiv fur Hydrobiologie, Supplement 50 - 53: 249 - 267." type="book chapter" year="1988">Komárek (1988: 391)</bibRefCitation>
</taxonomicName>
and 
<taxonomicName id="4C1614F16C4FFFA501C9FF0AFB81FF2F" authority="Richter ex Hansgirg (1892: 491)" authorityName="Richter ex Hansgirg" authorityPageNumber="491" authorityYear="1892" box="[475,1049,160,185]" class="Cyanophyceae" family="Oscillatoriaceae" genus="Lyngbya" kingdom="Bacteria" order="Nostocales" pageId="33" pageNumber="34" phylum="Cyanobacteria" rank="species" species="roseola">
<emphasis id="B962B3606C4FFFA501C9FF0AFD0FFF2F" box="[475,663,160,185]" italics="true" pageId="33" pageNumber="34">Lyngbya roseola</emphasis>
Richter 
<emphasis id="B962B3606C4FFFA502EFFF0AFC8EFF2F" box="[765,790,160,185]" italics="true" pageId="33" pageNumber="34">ex</emphasis>
Hansgirg (1892: 491)
</taxonomicName>
. Trichomes and cell dimensions fit well with 
<taxonomicName id="4C1614F16C4FFFA500ECFF6EFDBFFF4B" authorityName="Umezaki &amp; Watanabe" authorityYear="1994" baseAuthorityName="Gomont" baseAuthorityYear="1899" box="[254,551,196,221]" class="Cyanophyceae" family="Oscillatoriaceae" genus="Leptolyngbya" kingdom="Bacteria" order="Nostocales" pageId="33" pageNumber="34" phylum="Cyanobacteria" rank="species" species="cebennensis">
<emphasis id="B962B3606C4FFFA500ECFF6EFDBFFF4B" box="[254,551,196,221]" italics="true" pageId="33" pageNumber="34">Leptolyngbya cebennensis</emphasis>
</taxonomicName>
and 
<taxonomicName id="4C1614F16C4FFFA50271FF6EFCB8FF4B" authorityName="Richter ex Hansgirg" authorityYear="1892" box="[611,800,196,221]" class="Cyanophyceae" family="Oscillatoriaceae" genus="Lyngbya" kingdom="Bacteria" order="Nostocales" pageId="33" pageNumber="34" phylum="Cyanobacteria" rank="species" species="roseola">
<emphasis id="B962B3606C4FFFA50271FF6EFCB8FF4B" box="[611,800,196,221]" italics="true" pageId="33" pageNumber="34">Lyngbya roseola</emphasis>
</taxonomicName>
, although the characteristic of heterogeneity in width of young and mature trichomes as well as the absence of pseudobranches separate 
<taxonomicName id="4C1614F16C4FFFA503EDFF42FB19FE97" authorityName="Mai, Johansen et Pietrasiak" authorityYear="2018" box="[1023,1153,232,257]" class="Cyanobacteriia" family="Oculatellaceae" genus="Drouetiella" higherTaxonomySource="GBIF" kingdom="Bacteria" order="Synechococcales" pageId="33" pageNumber="34" phylum="Cyanobacteria" rank="species" species="hepatica">
<emphasis id="B962B3606C4FFFA503EDFF42FB19FE97" box="[1023,1153,232,257]" italics="true" pageId="33" pageNumber="34">D. hepatica</emphasis>
</taxonomicName>
from these taxa. 
<taxonomicName id="4C1614F16C4FFFA50553FF42FA34FE97" authorityName="Anagnostidis &amp; Komarek" authorityYear="1988" baseAuthorityName="Kutzing ex Lemmermann" baseAuthorityYear="1910" box="[1345,1452,232,257]" class="Cyanophyceae" family="Oscillatoriaceae" genus="Leptolyngbya" kingdom="Bacteria" order="Nostocales" pageId="33" pageNumber="34" phylum="Cyanobacteria" rank="species" species="carnea">
<emphasis id="B962B3606C4FFFA50553FF42FA34FE97" box="[1345,1452,232,257]" italics="true" pageId="33" pageNumber="34">L. carnea</emphasis>
</taxonomicName>
has granulated cell contents, tortuous trichomes and irregular sheath outlines that match filaments of 
<taxonomicName id="4C1614F16C4FFFA5050DFEA6FA3CFEB3" authorityName="Mai, Johansen et Pietrasiak" authorityYear="2018" box="[1311,1444,268,293]" class="Cyanobacteriia" family="Oculatellaceae" genus="Drouetiella" higherTaxonomySource="GBIF" kingdom="Bacteria" order="Synechococcales" pageId="33" pageNumber="34" phylum="Cyanobacteria" rank="species" species="hepatica">
<emphasis id="B962B3606C4FFFA5050DFEA6FA3CFEB3" box="[1311,1444,268,293]" italics="true" pageId="33" pageNumber="34">D. hepatica</emphasis>
</taxonomicName>
. However, 
<taxonomicName id="4C1614F16C4FFFA500EDFE9AFE1CFEDF" authorityName="Mai, Johansen et Pietrasiak" authorityYear="2018" box="[255,388,304,329]" class="Cyanobacteriia" family="Oculatellaceae" genus="Drouetiella" higherTaxonomySource="GBIF" kingdom="Bacteria" order="Synechococcales" pageId="33" pageNumber="34" phylum="Cyanobacteria" rank="species" species="hepatica">
<emphasis id="B962B3606C4FFFA500EDFE9AFE1CFEDF" box="[255,388,304,329]" italics="true" pageId="33" pageNumber="34">D. hepatica</emphasis>
</taxonomicName>
has wider trichomes, and brownish rather than pinkish coloration. No lamellate sheath was reported in any of the above species.
</paragraph>
<paragraph id="8BA96F726C4FFFA500AFFED2FF4BFC8B" blockId="33.[136,1452,160,797]" pageId="33" pageNumber="34">
<taxonomicName id="4C1614F16C4FFFA500AFFED2FEA7FE07" authorityName="Mai, Johansen et Pietrasiak" authorityYear="2018" box="[189,319,376,401]" class="Cyanobacteriia" family="Oculatellaceae" genus="Drouetiella" higherTaxonomySource="GBIF" kingdom="Bacteria" order="Synechococcales" pageId="33" pageNumber="34" phylum="Cyanobacteria" rank="species" species="hepatica">
<emphasis id="B962B3606C4FFFA500AFFED2FEA7FE07" box="[189,319,376,401]" italics="true" pageId="33" pageNumber="34">D. hepatica</emphasis>
</taxonomicName>
is distinct from the other named 
<taxonomicName id="4C1614F16C4FFFA502A3FED2FC11FE07" box="[689,905,376,401]" pageId="33" pageNumber="34">
<emphasis id="B962B3606C4FFFA502A3FED2FCA9FE07" box="[689,817,376,401]" italics="true" pageId="33" pageNumber="34">Drouetiella</emphasis>
species
</taxonomicName>
based on percent dissimilarity of the ITS region, which is&gt;18% (
<tableCitation id="C6945AC96C4FFFA5012EFE36FE39FE23" box="[316,417,412,437]" captionStart="TABLE 10" captionStartId="27.[136,224,971,994]" captionText="TABLE 10. ITS genetic similarity among Drouetiella species." pageId="33" pageNumber="34">Table 10</tableCitation>
). This very well satisfies the criterion for species distinction based on percent dissimilarity of&gt;4.0% (
<bibRefCitation id="EF8712836C4FFFA500F3FE6AFE71FE4F" author="Erwin, P. M. &amp; Thacker, R. W." box="[225,489,448,473]" pageId="33" pageNumber="34" pagination="2937 - 2947" refId="ref32378" refString="Erwin, P. M. &amp; Thacker, R. W. (2008) Cryptic diversity of the symbiotic cyanobacterium Synechococcus spongiarum among sponge host. Molecular Ecology 17: 2937 - 2947. https: // doi. org / 10.1111 / j. 1365 - 294 X. 2008.03808. x" type="journal article" year="2008">Erwin &amp; Thacker 2008</bibRefCitation>
, 
<bibRefCitation id="EF8712836C4FFFA501E6FE6AFC8EFE4F" author="Osorio-Santos, K. &amp; Pietrasiak, N. &amp; Bohunicka &amp; Miscoe, L. H. &amp; Kovacik L. &amp; Martin, M. P. &amp; Johansen J. R." box="[500,790,448,473]" pageId="33" pageNumber="34" pagination="450 - 470" refId="ref35905" refString="Osorio-Santos, K., Pietrasiak, N., Bohunicka, Miscoe, L. H., Kovacik L., Martin, M. P. &amp; Johansen J. R. (2014) Seven new species of Oculatella (Pseudanabaenales, Cyanobacteria): taxonomically recognizing cryptic diversification. European Journal of Phycology 49: 450 - 470. https: // doi. org / 10.1080 / 09670262.2014.976843" type="journal article" year="2014">
Osorio-Santos 
<emphasis id="B962B3606C4FFFA5028EFE6AFD4CFE4F" box="[668,724,448,473]" italics="true" pageId="33" pageNumber="34">et al.</emphasis>
2014
</bibRefCitation>
, 
<bibRefCitation id="EF8712836C4FFFA50330FE6AFB8AFE4F" author="Pietrasiak, N. &amp; Muhlsteinova, R. &amp; Siegesmund, M. A. &amp; Johansen, J. R." box="[802,1042,448,473]" pageId="33" pageNumber="34" pagination="529 - 541" refId="ref36149" refString="Pietrasiak, N., Muhlsteinova, R., Siegesmund, M. A. &amp; Johansen, J. R. (2014) Phylogenetic placement of Symplocastrum (Phormidiaceae, Cyanophyceae) with a new combination S. californicum and two new species: S. fletchnerae and S. torsivum. Phycologia 53: 529 - 541. https: // doi. org / 10.2216 / 14 - 029.1" type="journal article" year="2014">
Pietrasiak 
<emphasis id="B962B3606C4FFFA50385FE6AFC48FE4F" box="[919,976,448,473]" italics="true" pageId="33" pageNumber="34">et al.</emphasis>
2014
</bibRefCitation>
, 
<bibRefCitation id="EF8712836C4FFFA5040FFE6AFA82FE4F" author="Bohunicka, M. &amp; Pietrasiak, N. &amp; Johansen, J. R. &amp; Gomez, E. B. &amp; Hauer, T. &amp; Gaysina, L. A. &amp; Lukesova, A." box="[1053,1306,448,473]" pageId="33" pageNumber="34" pagination="84 - 103" refId="ref31113" refString="Bohunicka, M., Pietrasiak, N., Johansen, J. R., Gomez, E. B., Hauer, T., Gaysina, L. A. &amp; Lukesova, A. (2015) Rohotiella, gen. nov. (Nostocales, Cyanobacteria) - a tapering and branching cyanobacteria of the family Nostocaceae. Phytotaxa 197 (2): 84 - 103. https: // doi. org / 10.11646 / phytotaxa. 197.2.2" type="journal article" year="2015">
Bohunická 
<emphasis id="B962B3606C4FFFA5048CFE6AFB4EFE4F" box="[1182,1238,448,473]" italics="true" pageId="33" pageNumber="34">et al.</emphasis>
2015
</bibRefCitation>
). The closest taxon to 
<taxonomicName id="4C1614F16C4FFFA500FBFE4EFEF3FE6B" authorityName="Mai, Johansen et Pietrasiak" authorityYear="2018" box="[233,363,484,509]" class="Cyanobacteriia" family="Oculatellaceae" genus="Drouetiella" higherTaxonomySource="GBIF" kingdom="Bacteria" order="Synechococcales" pageId="33" pageNumber="34" phylum="Cyanobacteria" rank="species" species="hepatica">
<emphasis id="B962B3606C4FFFA500FBFE4EFEF3FE6B" box="[233,363,484,509]" italics="true" pageId="33" pageNumber="34">D. hepatica</emphasis>
</taxonomicName>
is a strain that was named 
<taxonomicName id="4C1614F16C4FFFA5028AFE4EFC74FE6B" authority="ANT. LH" authorityName="ANT. LH" box="[664,1004,484,509]" class="Cyanophyceae" family="Oscillatoriaceae" genus="Leptolyngbya" kingdom="Bacteria" order="Nostocales" pageId="33" pageNumber="34" phylum="Cyanobacteria" rank="species" species="frigida">
<emphasis id="B962B3606C4FFFA5028AFE4EFC1BFE6B" box="[664,899,484,509]" italics="true" pageId="33" pageNumber="34">Leptolyngbya frigida</emphasis>
ANT.LH
</taxonomicName>
52.2 by the researchers that found it and subsequently reported on it (
<bibRefCitation id="EF8712836C4FFFA501DEFDA2FD0BFDB7" author="Taton, A. &amp; Grubisic, S. &amp; Hodson, D. A. &amp; Piccardi, R. &amp; Biondi, N. &amp; Tredici, M. R. &amp; Mainini, M. &amp; Daniele, L. &amp; Marinelli, F. &amp; Wilmotte, A." box="[460,659,520,545]" pageId="33" pageNumber="34" pagination="1257 - 1270" refId="ref37660" refString="Taton, A., Grubisic, S., Ertz, D., Hodson, D. A., Piccardi, R., Biondi, N., Tredici, M. R., Mainini, M., Daniele, L., Marinelli, F. &amp; Wilmotte, A. (2006) Polyphasic study of Antartic cyanobacterial strains. Journal of Phycology 42: 1257 - 1270. https: // doi. org / 10.1111 / j. 1529 - 8817.2006.00278. x" type="journal article" year="2006">
Taton 
<emphasis id="B962B3606C4FFFA50204FDA2FDC8FDB7" box="[534,592,520,545]" italics="true" pageId="33" pageNumber="34">et al.</emphasis>
2006
</bibRefCitation>
, 
<bibRefCitation id="EF8712836C4FFFA502B2FDA2FCF4FDB7" author="Sabbe, K. &amp; Hodgson, D. A. &amp; Verleyen, E. &amp; Taton, A. &amp; Wilmotte, A. &amp; Vanhoutte, K. &amp; Vyverman, W." box="[672,876,520,545]" pageId="33" pageNumber="34" pagination="296 - 319" refId="ref36614" refString="Sabbe, K., Hodgson, D. A., Verleyen, E., Taton, A., Wilmotte, A., Vanhoutte, K. &amp; Vyverman, W. (2004) Salinity, depth and the structure and composition of microbial mats in continental Antartic lakes. Freshwater Biology 49: 296 - 319. https: // doi. org / 10.1111 / j. 1365 - 2427.2004.01186. x" type="journal article" year="2004">
Sabbe 
<emphasis id="B962B3606C4FFFA502FFFDA2FCBEFDB7" box="[749,806,520,545]" italics="true" pageId="33" pageNumber="34">et al.</emphasis>
2004
</bibRefCitation>
). 
<collectionCode id="ED07F7B76C4FFFA5036CFDA2FC21FDB7" box="[894,953,520,545]" country="0" httpUri="http://grbio.org/cool/1k5k-ghgz" name="Anguilla National Trust" pageId="33" pageNumber="34" type="Herbarium">ANT</collectionCode>
.LH52.2 has high 16S rRNA gene similarity to 
<taxonomicName id="4C1614F16C4FFFA500BAFD86FEB5FDD3" authorityName="Mai, Johansen et Pietrasiak" authorityYear="2018" box="[168,301,556,581]" class="Cyanobacteriia" family="Oculatellaceae" genus="Drouetiella" higherTaxonomySource="GBIF" kingdom="Bacteria" order="Synechococcales" pageId="33" pageNumber="34" phylum="Cyanobacteria" rank="species" species="hepatica">
<emphasis id="B962B3606C4FFFA500BAFD86FEB5FDD3" box="[168,301,556,581]" italics="true" pageId="33" pageNumber="34">D. hepatica</emphasis>
</taxonomicName>
(99.5% identity), but dissimilarity in the ITS regions between two taxa is well above the 4% level used as evidence of conspecificity. Both taxa have identical domain lengths in the ITS region (
<tableCitation id="C6945AC96C4FFFA504DDFDFAFAB1FDFF" box="[1231,1321,592,617]" captionStart="TABLE 6" captionStartId="14.[136,224,161,184]" captionText="TABLE 6. Length of regions within the ITS structure of species within family Oculatellaceae." pageId="33" pageNumber="34">Table 6</tableCitation>
). The most striking similarity between the two taxa is the near complete similarity of secondary structure of the conserved ITS domains (
<figureCitation id="132D73F76C4FFFA500E4FD32FEFBFD27" box="[246,355,664,689]" captionStart-0="FIGURE 6" captionStart-1="FIGURE 7" captionStart-2="FIGURE 8" captionStart-3="FIGURE 9" captionStartId-0="15.[136,229,1976,1997]" captionStartId-1="17.[136,229,1928,1949]" captionStartId-2="18.[136,229,1187,1208]" captionStartId-3="19.[136,229,1958,1979]" captionTargetBox-0="[157,1425,273,1857]" captionTargetBox-1="[314,1274,759,1806]" captionTargetBox-2="[152,1434,425,1107]" captionTargetBox-3="[229,912,769,1871]" captionTargetId-0="figure-14@15.[151,1436,267,1882]" captionTargetId-1="figure-238@17.[311,1276,751,1831]" captionTargetId-2="figure-143@18.[151,1436,422,1162]" captionTargetId-3="figure-135@19.[151,1436,768,1875]" captionTargetPageId-0="15" captionTargetPageId-1="17" captionTargetPageId-2="18" captionTargetPageId-3="19" captionText-0="FIGURE 6. D1-D1’ stems of species described in Oculatellaceae.The stem structures of genera described previously in other publications (Oculatella, Thermoleptolyngbya, Timaviella) or in publications under provision (Trichotorquatus) are not shown here." captionText-1="FIGURE 7. Box B helices of species described in Oculatellaceae. The structures of genera described previously in other publications (Oculatella, Thermoleptolyngbya, Timaviella) or in publications under provision (Trichotorquatus) are not shown here." captionText-2="FIGURE 8. V2 helices of species described in Oculatellaceae. Several species do not have this structure, including Pegethrix convoluta, P. indistincta, Antartic Pegethrix species, Cartusia fontana¸ Kaiparowitsia implicata." captionText-3="FIGURE 9. V3 helices of species described in Oculatellaceae. All species described have this structure. The V3 helix of Cartusia aeruginosa is missing because we do not have the full length of its ITS region." pageId="33" pageNumber="34">Figs. 6–9</figureCitation>
). We do not know the morphology of 
<collectionCode id="ED07F7B76C4FFFA5031EFD32FCDDFD27" box="[780,837,664,689]" country="0" httpUri="http://grbio.org/cool/1k5k-ghgz" name="Anguilla National Trust" pageId="33" pageNumber="34" type="Herbarium">ANT</collectionCode>
LH52.2, so a decision as to whether or not to consider it conspecific with 
<taxonomicName id="4C1614F16C4FFFA5014FFD16FE47FD43" authorityName="Mai, Johansen et Pietrasiak" authorityYear="2018" box="[349,479,700,725]" class="Cyanobacteriia" family="Oculatellaceae" genus="Drouetiella" higherTaxonomySource="GBIF" kingdom="Bacteria" order="Synechococcales" pageId="33" pageNumber="34" phylum="Cyanobacteria" rank="species" species="hepatica">
<emphasis id="B962B3606C4FFFA5014FFD16FE47FD43" box="[349,479,700,725]" italics="true" pageId="33" pageNumber="34">D. hepatica</emphasis>
</taxonomicName>
must be postponed until more information is available, but the evidence that this strain and associated sequence belong to 
<taxonomicName id="4C1614F16C4FFFA5021EFD4AFD14FD6F" authorityName="Mai, Johansen et Pietrasiak" authorityYear="2018" box="[524,652,736,761]" class="Cyanobacteriia" family="Oculatellaceae" genus="Drouetiella" higherTaxonomySource="GBIF" kingdom="Bacteria" order="Synechococcales" pageId="33" pageNumber="34" phylum="Cyanobacteria" rank="genus">
<emphasis id="B962B3606C4FFFA5021EFD4AFD14FD6F" box="[524,652,736,761]" italics="true" pageId="33" pageNumber="34">Drouetiella</emphasis>
</taxonomicName>
is unequivocable. It is discussed further under Antarctic 
<taxonomicName id="4C1614F16C4FFFA50517FD4AFA33FD6F" box="[1285,1451,736,761]" class="Cyanobacteriia" family="Oculatellaceae" genus="Drouetiella" kingdom="Bacteria" order="Synechococcales" pageId="33" pageNumber="34" phylum="Cyanobacteria" rank="species" species="undetermined">
<emphasis id="B962B3606C4FFFA50517FD4AFA1DFD6F" box="[1285,1413,736,761]" italics="true" pageId="33" pageNumber="34">Drouetiella</emphasis>
sp.
</taxonomicName>
above.
</paragraph>
</subSubSection>
</treatment>
</document>