Petalomonas

Petalomonas
Scientific classification
Domain:	Eukaryota
Phylum:	Euglenozoa
Class:	Euglenophyceae
Order:	Petalomonadida
Family:	Scytomonadidae
Genus:	Petalomonas; F. Stein, 1859

Petalomonas is a genus of phagotrophic, flagellated euglenoids.^[1] Phagotrophic euglenoids are one of the most important forms of flagellates in benthic aquatic systems, playing an important role in microbial food webs.^[2] The traits that distinguish this particular genus are highly variable, especially at higher taxa.^[2] However, general characteristics such as a rigid cell shape and single emergent flagellum can describe the species among this genus.

History of knowledge

Petalomonas was first described by Dr. Friedrich Stein, a zoologist at the University of Prague, in 1859.^[3]

Habitat and ecology

Petalomonas is a cosmopolitan genus, most abundant in fresh water with a few species observed in marine environments.^[1]^[4] These euglenoids mainly reside in muddy sediments as benthic organisms.^[5] The cells are phagotrophic, feeding on bacteria, and/or osmotophic, assimilating nutrients from its surroundings.^[1]^[6]

Description

These non-metabolic, colourless cells range in size from 8–45 um, with a general flattened, leaf-like shape.^[1] The posterior end is rounded or truncate and the anterior end is narrowed; however, cells can span from ovoid, to fusiform or triangular, to elongately oval.^[1]^[4] A distinguishing feature of the euglenoids is the presence of proteinaceous pellicle strips that are underlined with microtubules.^[7] In Petalomonas, cells are covered with approximately a dozen thickly, fused pellicle strips making the cell very rigid and possibly resistant to surface ice crystal formation that can disrupt the cell.^[7] These pellicle strips, unlike most euglenoids, are lacking grooves or troughs; however, species specific pellicle features, such as pleat-like thickenings at the joints of pellicle strips, that characterize P. cantuscygni, can distinguish certain species.^[5] Strong ribs or keels are also evident in these cells, which can be arranged spirally or relatively straight, ranging in width.^[1]^[4] Some species may contain furrows that vary in size and depth, and can be located dorsally and/or ventrally on the body of the cell.^[4] The cells also have an abundance of paramylon bodies, typically used for the storage of starch, that are observed in all species.^[1]^[4]

The feeding structure, not visible under light microscopy, is relatively simple consisting of a pocket-like cavity ending with a cytostome, lined with microtubules for phagocytosis.^[8]^[5] The cells within this genus are also defined by one emergent flagellum extending from a sub-apical opening, directed anteriorly when swimming.^[1]^[7]^[4] The movement of this flagellum is very minimal with some vibration at the tip; however, some species are observed to have vigorously, whipping flagellum that result in rapid rotation and oscillation of the cell body.^[4] These euglenoids have also been observed to glide forward using the body, while the flagellum is used to contact the substrate.^[7]^[4] The nucleus is located centrally to the left side of the cell.^[4]

Life history

In euglenoids, sexual reproduction is unknown; however, asexual reproduction has been observed to occur in this genus through longitudinal fission, where the division occurs very quickly, starting at the anterior end of the cell.^[6]

List of species

Petalomonas abscissa (Dujardin) Stein
Petalomonas acuminata Hollande
Petalomonas africana Bourrelly
Petalomonas alata (A.C. Stokes) A.C. Stokes
Petalomonas applanata Skuja
Petalomonas arcuata Hollande
Petalomonas asymmetrica Schawhan & Jahn
Petalomonas bicarinata Shawhan & Jahn
Petalomonas calycimonadoides Christen
Petalomonas calycimonoides W.J.Lee & D.J.Patterson
Petalomonas cantuscygni J.Cann & N.Pennick
Petalomonas carinata A.C.Stokes
Petalomonas christenii W.J.Lee & D.J.Patterson
Petalomonas conchata Christen
Petalomonas curvata Skuja
Petalomonas dentata Christen
Petalomonas dilatata Hollande
Petalomonas dorsalis Stokes
Petalomonas dubosqui Hollande
Petalomonas excavata Skuja
Petalomonas gibbera Christen
Petalomonas gigas Skuja
Petalomonas hyalina Christen
Petalomonas inflexa G.A.Klebs
Petalomonas intorta W.J.Lee & D.J.Patterson
Petalomonas involuta Skuja
Petalomonas irregularis Skuja
Petalomonas iugosa W.J.Lee & D.J.Patterson
Petalomonas klebsii Christen
Petalomonas klinostoma Skuja
Petalomonas labrum W.J.Lee & D.J.Patterson
Petalomonas lata Christen
Petalomonas mediocanellata F. Stein
Petalomonas messikommeri Christen
Petalomonas micra R.E.Norris
Petalomonas minor Larson & D.J. Patterson
Petalomonas minuta Hollande
Petalomonas minutula Christen
Petalomonas mira Awerinzew
Petalomonas ornata Skvortzov
Petalomonas ovata Skvortzov
Petalomonas ovum Matvienko
Petalomonas paludosa Christen
Petalomonas pentacarinata Péterfi
Petalomonas phacoides Skuja
Petalomonas plana W.J.Lee & D.J.Patterson
Petalomonas platyrhyncha Skuja
Petalomonas pluteus Christen
Petalomonas praegnans Skuja
Petalomonas pringsheimii Christen
Petalomonas prototheca Skuja
Petalomonas punctato-striata Skuja
Petalomonas pusilla Skuja
Petalomonas quadrilineata Penard
Petalomonas quinquecarinata Hollande
Petalomonas quinquemarginata Shawhan & Jahn
Petalomonas robusta Christen
Petalomonas septemcarinata Shawhan & Jahn
Petalomonas sexlobata Klebs
Petalomonas simplex Christen
Petalomonas sinica Skvortzov
Petalomonas sinuata F.Stein
Petalomonas sphagnicola Tschermak-Woess
Petalomonas sphagnophila Christen
Petalomonas spinifera (Lackey) W.J.Lee & D.J.Patterson
Petalomonas splendens Hollande
Petalomonas steinii Klebs
Petalomonas stellata Skvortzov
Petalomonas sulcata A.C.Stokes
Petalomonas tenuis Christen
Petalomonas triangula Z.X.Shi
Petalomonas tricarinata Skuja
Petalomonas triquetra Skvortzov
Petalomonas variabilis Christen
Petalomonas ventritracta Skuja
Petalomonas virgata W.J.Lee & D.J.Patterson
Petalomonas vulgaris Skuja
Petalomonas wuhanica Z.Shi

References

^ ^a ^b ^c ^d ^e ^f ^g ^h Guiry, M. D.; Guiry, G. M. (2002). “Petalomonas F.Stein 1859”. Retrieved February 10, 2019, from [1]
^ ^a ^b Lax, G.; Simpson, A. G. (2013). “Combining Molecular Data with Classical Morphology for Uncultured Phagotrophic Euglenids (Excavata): A Single-Cell Approach”. Journal of Eukaryotic Microbiology. 60 (6): 615-625. doi:10.1111/jeu.12068
^ Stein, F. (1859). Der Organismus der Infusionsthiere nach eigenen Forschungen in systematischer Reihenfolge bearb. von Friedrich Stein. doi:10.5962/bhl.title.3933
^ ^a ^b ^c ^d ^e ^f ^g ^h ⁱ Shawhan, F. M.; Jahn, T. L. (1947). “A Survey of the Genus Petalomonas Stein (Protozoa: Euglenida)”. Transactions of the American Microscopical Society. 66 (2): 182. doi:10.2307/3223249
^ ^a ^b ^c Cavalier-Smith, Thomas; Chao, Ema E.; Vickerman, Keith (2016). “New phagotrophic euglenoid species (new genus Decastava; Scytomonas saepesedens; Entosiphon oblongum), Hsp90 introns, and putative euglenoid Hsp90 pre-mRNA insertional editing”. European Journal of Protistology. 56: 147-170. doi:10.1016/j.ejop.2016.08.002
^ ^a ^b Esson, H. J.; Leander, B. S. (2006). “A model for the morphogenesis of strip reduction patterns in phototrophic euglenids: Evidence for heterochrony in pellicle evolution”. Evolution Development, 8 (4): 378-388. doi:10.1111/j.1525-142x.2006.00110.x
^ ^a ^b ^c ^d Larsen, Jacob; Patterson, David J. (1990). "Some flagellates (Protista) from tropical marine sediments”. Journal of Natural History, 24 (4): 801-937. doi:10.1080/00222939000770571
^ Breglia, Susana A.; Yubuki, N.; Leander, Brian S. (2013). “Ultrastructure and Molecular Phylogenetic Position of Heteronema scaphurum: A Eukaryovorous Euglenid with a Cytoproct”. Journal of Eukaryotic Microbiology. 2: 107-120. doi: 10.1111/jeu.12014

[Guiry-1] ^ ^a ^b ^c ^d ^e ^f ^g ^h Guiry, M. D.; Guiry, G. M. (2002). “Petalomonas F.Stein 1859”. Retrieved February 10, 2019, from [1]

[Lax-2] Lax, G.; Simpson, A. G. (2013). “Combining Molecular Data with Classical Morphology for Uncultured Phagotrophic Euglenids (Excavata): A Single-Cell Approach”. Journal of Eukaryotic Microbiology. 60 (6): 615-625. doi:10.1111/jeu.12068

[3] Stein, F. (1859). Der Organismus der Infusionsthiere nach eigenen Forschungen in systematischer Reihenfolge bearb. von Friedrich Stein. doi:10.5962/bhl.title.3933

[Shawhan-4] ^ ^a ^b ^c ^d ^e ^f ^g ^h ⁱ Shawhan, F. M.; Jahn, T. L. (1947). “A Survey of the Genus Petalomonas Stein (Protozoa: Euglenida)”. Transactions of the American Microscopical Society. 66 (2): 182. doi:10.2307/3223249

[Cavalier-5] Cavalier-Smith, Thomas; Chao, Ema E.; Vickerman, Keith (2016). “New phagotrophic euglenoid species (new genus Decastava; Scytomonas saepesedens; Entosiphon oblongum), Hsp90 introns, and putative euglenoid Hsp90 pre-mRNA insertional editing”. European Journal of Protistology. 56: 147-170. doi:10.1016/j.ejop.2016.08.002

[Esson-6] Esson, H. J.; Leander, B. S. (2006). “A model for the morphogenesis of strip reduction patterns in phototrophic euglenids: Evidence for heterochrony in pellicle evolution”. Evolution Development, 8 (4): 378-388. doi:10.1111/j.1525-142x.2006.00110.x

[Larsen-7] Larsen, Jacob; Patterson, David J. (1990). "Some flagellates (Protista) from tropical marine sediments”. Journal of Natural History, 24 (4): 801-937. doi:10.1080/00222939000770571

[8] Breglia, Susana A.; Yubuki, N.; Leander, Brian S. (2013). “Ultrastructure and Molecular Phylogenetic Position of Heteronema scaphurum: A Eukaryovorous Euglenid with a Cytoproct”. Journal of Eukaryotic Microbiology. 2: 107-120. doi: 10.1111/jeu.12014

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