Etymology
The word “Diplonemidae” come from the Greek words ‘diplo’, meaning two, and ‘nemat’, meaning thread. Together, Diplonemidae roughly translates to ‘two threads’, likely referring to the characteristic two flagella of the organism.History of Knowledge
Primary studies done in the 1900s by Griessmann and Skuja had initially grouped Diplonemidae (or more specifically, the '' Diplonema'' and ''Rhynchopus'' taxa) with the euglenids. This was due to the two groups sharing many morphological similarities with theHabitat and Ecology
Although Diplonemidae are generally predators, some species display parasitic life strategies. Diplonemidae display a rich diversity in marine and freshwater environments, with their relative abundance increasing with depth. The diplonemids that exist in these different environments are genetically distinct, and exhibit slightly different lifestyles. The ‘classic’ diplonemids (i.e. ''Diplonema'' and ''Rhynchopus'') are benthic, whereas the marine diplonemids, which include ''Hemistasia'', are planktonic. There are potentially thousands of unknown marine Diplonemidae species, with this diversity highly stratified in accordance to depth. Although molecular sequencing confirms the existence of these unnamed marine Diplonemidae, information regarding their morphology and lifestyle is absent. As marine ''Diplonemidae'' are the most abundant and genetically diverse protists (and potentially eukaryotes) in the sea, there are strong implications that they play a key role in aquatic ecosystems. As of now, this exact role is unknown.Description of the Organism
Morphology and Anatomy
Classical diplonemids (i.e. ''Diplonema'' and ''Rhynchopus''), are colourless and oblong in shape. They are approximately 20 μm in length and possess a microtubule layer underneath their plasma membrane. Adjacent to it is a mitochondrion with discoidal cristae. They also possess two flagella of equal length, both of which lack paraxial rods. The two basal bodies originate from a subapical pocket, which merges with an adjacent feeding apparatus. This feeding apparatus is surrounded by many food vacuoles and reinforced by microtubules. Nonclassical ''Diplonemidae'' (i.e. ''Hemistasia)'' are diverse in size but share many morphological aspects with the classic diplonemids. However, a great majority of these marine ''Diplonemidae'' have never been seen, with their existence only confirmed through molecular analysis. Although ''Diplonemidae'' do not possess pellicular strips like ''Euglenids'', they still move via metaboly. ''Diplonemidae'' also exhibit the compartmentalization of glycolytic and gluconeogenic enzymes into peroxisomes. These organelles are referred to as glycosomes, and is a characteristic feature also shared with their sister taxon, the '' kinetoplastids''.Life cycles
''Diplonemidae'' are capable of sexual reproduction, as genes involved in meiosis have been found. Although marine diplonemids appear to reproduce sexually, not much is known about ''Diplonemidae'' reproduction as '' Euglenozoans'' rarely demonstrate sexual processes.Genetics
''Diplonemidae'' have a very unique mitochondrial DNA arrangement. Although ''Diplonemidae'' possess a large mitochondrial genome, these do not contain any intact full-sized genes. Instead, their mitochondrial DNA consists of linear gene fragments of different sizes. Because each fragment is both full of repeats and incomplete, individually they are unable to code for a gene themselves. Instead, fragments are transcribed and spliced together using their own specialized trans splicing machinery. Once spliced together, the transcript undergoes extensive editing to become recognizable RNA. This is accomplished by either Uracil-insertion, nucleotide deanimation, or substitution, which eventually generates a fully mature and translatable transcript. The ''Diplonemidae'' genome contains a spliced leader RNA gene, which confirms their use of mRNA spliceosome-dependent trans splicing during nuclear expression. Diplonemids possess the ''gap3'' gene which is specifically found in cyanobacteria and Pseudomonadota. This is likely due to lateral gene transfer following the divergence of diplonemids from the ''Euglenoids''. As to date, this is one of the most-supported examples of lateral gene transfer from a bacterium to eukaryote and may have implications for diplonemid acquisition of biochemical abilities.Taxonomy
Although presently made up of less than a dozen named species, the existence of thousands of unknown ''Diplonemidae'' species has been confirmed. * Genus '' Diplonema'' Griessmann 1913 non Don 1837 ** '' D. aggregata'' Tashyreva et al. 2018 ** '' D. ambulator'' Larsen & Patterson 1990 ** '' D. breviciliata'' Griessman 1913 ** '' D. japonica'' Tashyreva et al. 2018 ** '' D. metabolica'' Larsen & Patterson 1990 ** '' D. nigricans'' (Schuster, Goldstein & Hershenow 1968) Triemer & Ott 1990 'Isonema nigricans'' Schuster, Goldstein & Hershenow 1968ref name=pmid23196044/> ** '' D. papillata'' (Porter 1973) Triemer & Ott 1990 'Isonema papillata'' Porter 1973ref name=pmid23196044/> * Genus '' Flectonema'' Tashyreva et al. 2018 ** '' F. neradi'' Tashyreva et al. 2018 * Genus '' Lacrimia'' Tashyreva et al. 2018 ** '' L. lanifica'' Tashyreva et al. 2018 * Genus '' Rhynchopus'' Skuja 1948 ** '' R. amitus'' Skuja 1948 ** '' R. coscinodiscivorus'' Schnepf 1994 ** '' R. euleeides'' Roy et al. 2007 ** '' R. humris'' Tashyreva et al. 2018 ** '' R. littoralensis'' Kufferath 1950 ** '' R. serpens'' Tashyreva et al. 2018 * '' Sulcionema'' Tashyreva et al. 2018 ** '' S. specki'' Tashyreva et al. 2018References
{{Taxonbar, from=Q8560156 Euglenozoa