identifier	taxonID	type	CVterm	format	language	title	description	additionalInformationURL	UsageTerms	rights	Owner	contributor	creator	bibliographicCitation
03AF5047FFA4A33CFF77F88A828759EE.text	03AF5047FFA4A33CFF77F88A828759EE.taxon	http://purl.org/dc/dcmitype/Text	http://rs.tdwg.org/ontology/voc/SPMInfoItems#GeneralDescription	text/html	en	Melanosternarchus Bernt & Crampton & Orfinger & Albert 2018	<div><p>Melanosternarchus, new genus</p><p>(Figs. 1–10; Table 1.)</p><p>Type species. Melanosternarchus amaru, new species, by monotypy and original designation.</p><p>Diagnosis. Melanosternarchus is diagnosed from all other apteronotid genera within the Navajini by bones 1– 4 of the infraorbital laterosensory canal present as tubes fused to expanded bony plates (versus only tubular-shaped bones in other genera), and overlapping contact between infraorbital bones 3 and 4 (versus these bones not contacting one another in other genera), see Fig. 3B. Melanosternarchus can be further distinguished from all other apteronotid genera by the following combination of readily-observable characters: 1) gape long, rictus located at or behind a vertical with the eye (vs. gape short, rictus located anterior to vertical with eye), 2) scales absent over entire dorsum (vs. scales completely or partly covering dorsum), 3) one or no teeth on the premaxilla (vs two more teeth on the premaxilla), and 4) dark brown body coloration, without a pale middorsal stripe (vs. pink, light-brown, black, or uneven body colorations, sometimes with a pale middorsal stripe).</p><p>Although Melanosternarchus is diagnosed from all known species within the Navajini by its platelike infraorbitals, this character can only be readily observed in cleared and stained specimens. We therefore provide additional characters by which it can be separated from all other Navajini genera. Melanosternarchus can be distinguished from the Apteronotus bonapartii group ( A. apurensis, A. bonapartii, and A. ellisi) by the following four characters: 1) one or no teeth on the premaxilla vs. 4 or more; 2) scales absent along entire dorsum from nape to dorsal organ, vs. large scales present along dorsal midline posterior to nape 3); dentary teeth forming a cluster of two short, irregular rows on the posterior region of the dentary, tapering into a single row anteriorly, vs. all dentary teeth arranged in two rows; 4) dorsal margin of lateral fenestra composed of orbitosphenoid and pterosphenoid, with the margin of these bones protruding ventrally into the fenestra vs. margin of orbitosphenoid and pterosphenoid anterior to lateral fenestra (i.e. dorsal margin of fenestra composed only of pterosphenoid). This condition is illustrated for A. apurensis in Albert (2001: fig. 14A), and for A. bonapartii in Hilton &amp; Cox Fernandes (2006: fig. 4, 2017: fig. 4).</p><p>Melanosternarchus can be distinguished from all species of Compsaraia by four characters: 1) the absence of an L-shaped (longer longitudinally than vertically) supratemporal lateral-line canal; 2) uniform brown coloration on the head and snout vs. pale patch of low melanophore density on snout in a narrow band, anterior to the eyes and lateral to nares; 3) four mandibular canal ossicles, all ventral to the lower jaw, vs. five ossicles present, with the posterior two ossicles ventral to the preopercle; 4) dark pigmentation present on pectoral and anal fins, vs. pigmentation absent from pectoral and anal fins.</p><p>Melanosternarchus can be distinguished from Pariosternarchus by five characters: 1) gape extending to or beyond vertical with the eye, vs. gape not reaching vertical with eye; 2) head not expanded ventrolaterally, vs. head expanded ventrolaterally (a condition associated with expanded mandibular canal-ossicles); 3) one or no teeth present on premaxilla vs. 6 or more teeth on premaxilla; 4) teeth forming a cluster of two short, irregular rows on the posterior region of the dentary, tapering into a single row anteriorly, vs. teeth arranged in two rows on the dentary; 5) urohyal without posterior ossified blade, vs. posterior ossified blade present.</p><p>Melanosternarchus can be distinguished from all species of Sternarchogiton except for S. porcinum Eigenmann &amp; Allen by gape extending to or beyond vertical with the eye vs. gape not reaching vertical with eye, and from S. porcinum by brown pigmentation on head and sides, vs. pink to pale straw color on head and sides.</p><p>Melanosternarchus can be distinguished from all Sternarchella by 1) gape extending to or beyond vertical with the eye, vs. gape not exceeding vertical with posterior naris and 2) one or no teeth on premaxilla vs. two to four rows of teeth on premaxilla.</p><p>Although there is not currently a diagnosis for Porotergus, Melanosternarchus can be distinguished from each species in the genus. It can be differentiated from P. gimbeli Ellis by one or no teeth on the premaxilla vs. 6–8 teeth on the premaxilla; from P. duende de Santana &amp; Crampton by gape extending to or beyond vertical with eye; and from P. gymnotus Ellis by 1) dentary teeth forming a cluster of two short, irregular rows on the posterior region of the dentary, tapering into a single row anteriorly, vs. teeth arranged in two rows on the dentary and 2) one or no teeth on premaxilla vs. two or more teeth on the premaxilla.</p><p>Etymology. Melano from the Greek melas, meaning black in reference to dark pigmentation and presence in blackwater rivers, and sternarchus, a name commonly used in apteronotid taxonomy, from the Greek sternon (chest) and archos (rectum), referring to the anterior position of the anus.</p></div>	https://treatment.plazi.org/id/03AF5047FFA4A33CFF77F88A828759EE	Public Domain	No known copyright restrictions apply. See Agosti, D., Egloff, W., 2009. Taxonomic information exchange and copyright: the Plazi approach. BMC Research Notes 2009, 2:53 for further explanation.		MagnoliaPress via Plazi	Bernt, Maxwell J.;Crampton, William G. R.;Orfinger, Alexander B.;Albert, James S.	Bernt, Maxwell J., Crampton, William G. R., Orfinger, Alexander B., Albert, James S. (2018): Melanosternarchus amaru, a new genus and species of electric ghost knifefish (Gymnotiformes: Apteronotidae) from the Amazon Basin. Zootaxa 4378 (4): 451-479, DOI: 10.11646/zootaxa.4378.4.1
03AF5047FFA0A335FF77FD5284415D43.text	03AF5047FFA0A335FF77FD5284415D43.taxon	http://purl.org/dc/dcmitype/Text	http://rs.tdwg.org/ontology/voc/SPMInfoItems#GeneralDescription	text/html	en	Melanosternarchus amaru Bernt & Crampton & Orfinger & Albert 2018	<div><p>Melanosternarchus amaru, new species</p><p>Holotype. MUSM 59405, 230 mm TL, Peru, Loreto, Maynas, Rio Nanay at <a href="https://tb.plazi.org/GgServer/search?materialsCitation.longitude=-73.28172&amp;materialsCitation.latitude=-3.753" title="Search Plazi for locations around (long -73.28172/lat -3.753)">Pampachica</a>, 03°45'10.8"S, 73°16'54.2"W, M. Bernt, A. Chota et al., 2 January 2016.</p><p>Paratypes. Peru: Loreto: ANSP 200451 (1), 262 mm TL and ANSP 200452 (1), 177 mm TL, Rio Nanay downstream from <a href="https://tb.plazi.org/GgServer/search?materialsCitation.longitude=-73.28655&amp;materialsCitation.latitude=-3.7239168" title="Search Plazi for locations around (long -73.28655/lat -3.7239168)">Pampachica</a>, 03°43'26.1"S 73°17'11.6"W, M. Bernt et al. , 4 July 2014. ANSP 200459 (12, 2 cleared and stained), 149–231, collected with holotype .</p><p>Nontypes. Brazil: Amazonas: ANSP 192675 (1), 160 mm TL, Rio Negro, 35 km downriver of Vila Guajará, 36 km upriver of <a href="https://tb.plazi.org/GgServer/search?materialsCitation.longitude=-62.233334&amp;materialsCitation.latitude=-1.2230556" title="Search Plazi for locations around (long -62.233334/lat -1.2230556)">Carvoeiro</a>, 01°13'23'' S 62°14'0''W, J. Lundberg et al., 11 December 1993 . ANSP 192676 (3), 165–250 mm TL, Rio Negro, 33.9 km downriver of Novo Caioe, 6.5 km upriver of S. Francisco de Assis, J. Lundberg et al., 5 December 1993 . FMNH 114883 (2), 138–149 mm TL, Rio Purus, between tributaries Boca do Lago do Estopa and <a href="https://tb.plazi.org/GgServer/search?materialsCitation.longitude=-61.46139&amp;materialsCitation.latitude=-3.9577777" title="Search Plazi for locations around (long -61.46139/lat -3.9577777)">Solimões</a>, between towns Surará and Beruri, 03°57'28" S 61°27'41"W, J. Lundberg et al., 27 July 1996 . FMNH 128388 (2), 208–210 mm TL, FMNH 128397 (1), 236 mm TL, and FMNH 128405 (1), 271 mm TL, Rio Negro near confluence with <a href="https://tb.plazi.org/GgServer/search?materialsCitation.longitude=-59.906334&amp;materialsCitation.latitude=-3.1401668" title="Search Plazi for locations around (long -59.906334/lat -3.1401668)">Rio Amazonas</a>, 03°08'24.6"S 059°54'22.8"W, V. Tagliacollo et al., 15 May 2016 . ZUEC 14195 (1), 272 mm TL, Solimões-Japurá confluence at Mamirauá Lake System, Paraná Maiana 03°06'36"S 064°47 04" W, W. Crampton, 28 January 1999 . Pará: ANSP 196460 (1), 235 mm TL, Rio Xingu, right bank, ca. 1.3 km northwest (downstream) of <a href="https://tb.plazi.org/GgServer/search?materialsCitation.longitude=-52.05&amp;materialsCitation.latitude=-40.083332" title="Search Plazi for locations around (long -52.05/lat -40.083332)">Porto de Moz</a>, 01°44' 40°5''S 52°14' 52°3''W, M. Arce et al., 3 April 2014 . LSUMZ 20733 (1), 237 mm TL and LSUMZ 20734 (1 cleared and stained), 239 mm TL, Rio Amazonas at Tocumatuba, near mouth of small channel connecting to <a href="https://tb.plazi.org/GgServer/search?materialsCitation.longitude=-54.796722&amp;materialsCitation.latitude=-2.2438889" title="Search Plazi for locations around (long -54.796722/lat -2.2438889)">Rio Tapajós</a>, 2°14'38''S 54°47'48.2''W, J. Albert et al., 19 June 2015 . LSUMZ 20732 (1), 198 mm TL, Rio Amazonas at Tocumatuba, ca. mouth of <a href="https://tb.plazi.org/GgServer/search?materialsCitation.longitude=-54.80686&amp;materialsCitation.latitude=-2.2322779" title="Search Plazi for locations around (long -54.80686/lat -2.2322779)">Rio Tapajós</a>, 2°13'56.2''S 54°48'24.7''W, M. Bernt et al., 21 June 2015 . Peru: Loreto: MUSM 59453 (19, 2 cleared and stained), 145–242 mm TL, Rio Nanay downstream from <a href="https://tb.plazi.org/GgServer/search?materialsCitation.longitude=-73.31502&amp;materialsCitation.latitude=-3.7618666" title="Search Plazi for locations around (long -73.31502/lat -3.7618666)">Santa Clara</a>, 03°45'42.72"S 073°18'54.06"W, M. Bernt et al., 5 January 2017 . MUSM 59450 (4), 135–172 mm TL, Rio Nanay at Pucayacu a <a href="https://tb.plazi.org/GgServer/search?materialsCitation.longitude=-73.31052&amp;materialsCitation.latitude=-3.7574832" title="Search Plazi for locations around (long -73.31052/lat -3.7574832)">Orillas</a>, 03°45'26.94"S 073°18'37.86"W, M. Bernt et al., 2 January, 2017 . MUSM 56870 (4), 161–170 mm TL, Rio Nanay near Iquitos at <a href="https://tb.plazi.org/GgServer/search?materialsCitation.longitude=-73.30547&amp;materialsCitation.latitude=-3.7130833" title="Search Plazi for locations around (long -73.30547/lat -3.7130833)">Puerta Camelias</a>, 03°42'47.1'' S 073°18'19.7''W, A. Orfinger et al., 23 December 2015 . ZUEC 14196 (1), 195 mm TL, beach near Playa Pampachica, A. Orfinger et al., 7 September 2015.</p><p>Diagnosis. As for the genus.</p><p>Description. Body shape and pigmentation illustrated in Figs 1–3. Summaries of morphometric data on body measurements and meristics are presented in Table 1. Largest recorded size 272 mm TL. Body laterally compressed, elongate and slender. Head and mouth large, rictus extending beyond vertical with eye. Mouth terminal or slightly inferior. Eye small, less than 10% head length, covered by thin layer of skin. Scales large and rhomboid forming 3–4 rows above lateral line at midbody. Scales absent on entire middorsum and patch over nape above lateral line to about 5th lateral-line pore. Nasal capsule closer to snout tip than to eye. Anterior nares tubular.</p><p>Neurocranium illustrated in Figs. 4 and 5. Paired frontals straight or slightly concave in dorsal profile and comprising about half total skull length. Posterior fontanelle about one-third longer than anterior fontanelle. Supraoccipital crest not exceeding dorsal margin of parietals. Parietals surround posterior half of posterior fontanelle, and frontals surround anterior half of posterior fontanelle. Mesethmoid strongly decurved and forked posteriorly, underlying nasals and bordering anterior fontanelle. Anterior tip of mesethmoid with bulbous, cartilaginous projection bearing short lateral processes that articulate with premaxillae. Ventral ethmoid robust with wing-like lateral processes contacting lateral ethmoid cartilage. Lateral ethmoids robust, broadest at dorsal articular surface and angled obliquely to neurocranial axis. Orbitosphenoid contacting frontals dorsally and parasphenoid at two points ventrally. Orbitosphenoid cartilaginous dorsally in specimens up to 200 mm TL. Orbitosphenoid contacts pterosphenoid posteriorly. Together with the parasphenoid, these bones form a prominent lateral fenestra. Margin of articulation between orbitosphenoid and pterosphenoid protrudes ventrally into anterior third of this fenestra. In one adult specimen (Fig. 4C), pterosphenoid bears posterior ventral process extending to parasphenoid (also present in Orthosternarchus tamandua Boulenger, Hilton et al., 2007: fig. 10B; Sternarchella schotti Steindachner and S. raptor Lundberg et al., Ivanyisky &amp; Albert, 2014: figs. 3B, F; and Compsaraia compsa Albert, Bernt &amp; Albert, 2017: fig. 5A). The parasphenoid is the largest element of the skull floor contacting the basioccipital and prootics posteriorly, and bifurcating anteriorly into sharply-pointed processes that reach the cartilage of the lateral ethmoids at or near its junction with the ventral ethmoid. Dorsal to the parasphenoid, the vomer tapers to a sharp point posteriorly and broadens anteriorly at its contact with the ventral ethmoid.</p><p>The braincase is composed of the basioccipital, supraoccipital and paired parietals, epiocciptals, exoccipitals, prootics, pterotics, and sphenotics. Supraoccipital crest low, not exceeding dorsal margin of parietals. Pterotics support horizontal semicircular canals (visible ventrally) and project laterally to the skull’s greatest width. Prootic and exoccipital with prominent foraminae. Basioccipital approximately triangular in ventral view, with deep medial groove and a circular patch of cartilage at its posterior base.</p><p>Suspensorium and oral jaws illustrated in Fig. 6. Opercle triangular with a slightly concave dorsal margin. This bone is reticulated and weakly ossified at its center, becoming more laminar at its distal margins. Interopercle teardrop shaped, more heavily ossified dorsomedially. Ventral extension is extremely thin and remains transparent after alizarin staining. Subopercle similarly thin and transparent along distal margin. Preopercle with vertically-oriented laterosensory canal tube on lateral surface. Hyomandibula oriented nearly 90° to long axis of skull, with ridge projecting posterolaterally, tightly articulating with dorsal half of preopercular anterior margin. Dorsal articulating head of hyomandibula about twice width of distal end. Prominent foramen associated with cranial nerves (V, VII, and lateral line nerves) visible on medial surface. Symplectic triangular, oblique to hyomandibula and separated by a thick band of cartilage. Metapterygoid triangular with dorsal and ventral sides about equal in length. Quadrate articulating ventroposteriorly with preopercle in two interlocking processes from each bone. Endopterygoid edentulous with a robust, vertical (i.e. perpendicular to bone’s dorsal surface) ascending process. Endopterygoid broadly overlapping with metapterygoid and quadrate (visible medially). Autopalatine cartilage extending from anterior tip of endopterygoid and abruptly curving ventrally to contact the articular surface of the maxilla.</p><p>The mandible is composed of the retroarticular, anguloarticular, dentary, coronomeckelian bones, and Meckel’s cartilage. Retroarticular small, roughly rectangular without anterior process overlapping with anguloarticular. Anguloarticular with short ventroposterior process overlapping ventral surface of retroarticular. Anteriorly, anguloarticular has a complex overlapping articulation with the dentary, most clearly seen in lateral view. Dentary with 17–24 recurved teeth at middle of dorsal (oral) margin, arranged in two irregular rows posteriorly and merging into a single row anteriorly. Teeth on inner row angled medially. Anterior 1/3 and posterior 1/4 of dentary lacking teeth. Dorsoposterior region of dentary forming short, sharply-tapering process. Meckel’s cartilage prominent on medial surface of mandible, slightly wider posteriorly than anteriorly. Dorsal to Meckel’s cartilage, coronomeckelian is visible as a slender, triangular sesamoid ossification.</p><p>Maxilla with anteroventral shelf and anterodorsal hook. Descending blade of maxilla gracile and extending only slightly below ventral margin of anteroventral shelf. Articular surface of maxilla with rounded, cartilaginous cap. Premaxilla semicircular to triangular in ventral view. Ventral surface flat. Dorsal surface with anterior ridge and posterior depression at point of articulation with mesethmoid. Premaxilla edentulous or with a single conical tooth in anterolateral corner (Fig. 7).</p><p>The elements of the ventral hyoid arch are illustrated in Fig. 8A. Posterior ceratohyal with prominent foramen on dorsolateral surface. Entire anterior surface of posterior ceratohyal contacting anterior ceratohyal. Expanded cartilaginous margin between ceratohyals forming prominent ventral protuberance. Dorsal hypohyal with deep dorsolateral pit or fossa. Ventral hypohyal nearly pyramidal (triangular in lateral view), with all sides of approximately equal length. Urohyal (Fig. 8B) without posterior blade. Dorsal surface of urohyal with medial ridge extending to 3/4 of bone’s length. Ventral surface with only a very short medial eminence. Four branchiostegals. Branchiostegal 1–3 contact the ventral surface of the anterior ceratohyal. Branchiostegal 1 and 2 slender and filamentous, broadest at dorsal end. Third branchiostegal scythe-shaped with thin, poorly-ossified ventral margin. Branchiostegal 4 axe-shaped with long, slender posterior process, thin, weakly-ossified bladelike descending process, and short, pointed anterior process.</p><p>The ventral components of the branchial basket are illustrated in Fig. 9A. Gill rakers ossified, but not contacting gill-arch bars. Basihyal with cartilaginous anterior tip and short ridge on posterodorsal surface. Second basibranchial hourglass-shaped, convex at anterior and posterior articular surfaces. Third basibranchial ossified, broader anteriorly than posteriorly. Basibranchials 4 and 5 unossified. First hypobranchials triangular and cartilaginous posteriorly. Second hypobranchials with anteromedial contact beneath second basibranchial. Third hypobranchials contacting medially posterior to third basibranchial. Ceratobranchials 1–3 roughly rectangular, with cartilaginous cap at dorsal tip. Ceratobranchial 4 with posteriorly-angled medial process at about midlength of bone. Four to six gill rakers associated with each of first four ceratobranchials. Fifth ceratobranchials contacting medially around a short, cylindrical element of cartilage. This piece of cartilage was tentatively identified by Hilton et al. (2007) as basibranchial 5 in Orthosternarchus tamandua (see their fig. 14). However, in Melanosternarchus, this structure lies posterior to two much larger elements that we identify as the last two basibranchials, making this structure between the fifth ceratobranchials of unknown identity. Posteromedial surface of ceratobranchial 5 bearing 13–15 sharply-pointed, conical teeth. Dorsal elements of the branchial basket illustrated in Fig. 9B. Epibranchials 1–3 approximately rectangular, associated with few (1–2) or no gill rakers. Epibranchial 3 with short anteromedial process contacting infrapharyngobranchial 3. Epibranchial 4 Y-shaped with elongate posteriorly- and medially-oriented processes, both contacting epibranchial 5. Epibranchial 5 L-shaped and entirely cartilaginous. Infrapharyngobranchials 1 and 2 broad posteriorly with thick cartilaginous articular surface contacting epibranchial laterally and next infrapharyngobranchial medially. Infrapharyngobranchial 3 cylindrical and cartilaginous. Region of articulation between infrapharyngobranchial 3 and epibranchial 4 bearing the upper pharyngobranchial tooth plate, which holds 10–12 conical teeth.</p><p>Cranial laterosensory canals illustrated in Fig. 3B. Three nasal canal-bones present as short, tubular ossicles. Elongate supraorbital canal fused with frontal bone. Antorbital bone present as small, triangular, laminar dermal ossification just below posterior nares. Infraorbital bones 1 and 2 fused with trifurcating anterior tubular ossifications, and a laminar dermal posterior ossification. Infraorbital 3 with ventral tubular ossification and laminar dermal projection dorsally. Infraorbital 4 with dorsal tube and a ventral laminar dermal projection extending posteriorly and anteriorly. Laminar dermal portions of infraorbitals 3 and 4 with broad, overlapping contact. These bones are not fused, however, as they readily separate in cleared and stained specimens. Infraorbitals 5 and 6 present only as thin, tubular canals. Infraorbital 5 very weakly ossified or absent in some specimens. Parietal canal independent from supraorbital, angled posteriorly. Otic canal present as a groove or incompletely-closed tube over anterior 2/3 to 3/4 length. Supratemporal canal short, not strongly angled dorsoposteriorly. Four free mandibular canals (2–5), present as distally-expanded ossicles. All ventrolateral to the mandible, with none ventral to preopercle. First mandibular canal present as foramen in anterior region of dentary (Fig. 6).</p><p>Elements of pectoral girdle illustrated in Fig. 10A (lateral view) and 10B (medial view). Posterior edge of cleithrum curved medially, wrapping around posterior margin of scapula. Two weakly-ossified, rectangular postcleithrae present on each side. About 2/3 of supracleithrum with overlapping contact to dorsal extension of cleithrum. Dorsal tip of supracleithrum forming notch-like articular surface for ventrally-broadened posttemporal. Anterodorsally angled laterosensory canal fused to posttemporal at point of contact with supracleithrum. Scapula broadest dorsally at contact with cleithrum, angling anteriorly to contact coracoid. Coracoid with dorsallyexpanded process contacting cleithrum near point of dorsal flexion and long, thin anterior process contacting ventral margin of cleithrum. Four irregularly-shaped proximal radials. Propterygium with broad cartilaginous base and long, slender process. Fifteen to 16 pectoral-fin rays. First ray about 1/3 length of other rays and surrounded for most of length by propterygium.</p><p>First four vertebrae forming Weberian apparatus. Fifth vertebra articulating with first rib. First rib robust and greatly expanded dorsoanteriorly, contacting enlarged fourth parapophysis forming ventrally-angled concavity. Fourteen to 15 precaudal vertebrae, counting the last vertebra not articulating with the large anterior-displaced hemal spine (demarcating the posterior margin of abdominal cavity). Alternate configurations of displaced hemal spines shown in Fig. 11. Anterior displaced hemal spine long and saber-shaped, curving anteroventrally. Anterior displaced hemal spine may be the only ventrally-extending element of its associated vertebra (Fig. 10A), or it may articulate anterior to a single normal hemal spine (Fig. 11B). Additionally, the anterior displaced hemal spine may articulate with a vertebra bearing both a normal hemal spine and a posterior displaced hemal spine (Fig. 11C). The parapophysis of the preceding (anterior) vertebra may extend posteroventrally to contact anterior displaced hemal spine dorsally. One or two posterior displaced hemal spines present, straight and usually angled anteriorly. One specimen (shown in Fig. 11B) shows a single anteriorly-angled posterior displaced hemal spine and two closelyjoined spines in the posteriorly angled position of the rest of the caudal hemal spines. Fig. 11A also shows three hemal spines articulating to one vertebra, but with two displaced spines angled anteriorly.</p><p>Anal fin with 167–181 rays (mode = 178). Anal fin pterygiophores longer than displaced hemal spines. Pterygiophores broadened ventrally into thin, symmetrical vanes above articulating head. Caudal fin small and lanceolate in undamaged or fully regenerated specimens, with 12–16 (mode = 14) rays. Number of rays higher in specimens with regenerated caudal fins.</p><p>No secondary sexual dimorphism was observed in the cranial morphology or dentition of this species. Females could be recognized externally by their swollen abdomens or internally by mature ovaries containing large (1–2 mm in diameter), orange-yellow translucent eggs. Adult males were recognized by their opaque, cream-colored testes.</p><p>Color pattern, Dense brown chromatophores covering dorsum and sides, becoming more diffuse on skin overlaying pterygiophore musculature. Chromatophores arranged in series between pterygiophores forming thin, narrowly-spaced dark bars. Margin of upper lip and lower jaw white or cream-colored with few chromatophores. Opercle darkened by underlying gill filaments. Ground color in life gray to brown dorsally and pale pink over analfin pterygiophores. Head, dorsum, and dorsal organ speckled with pale-colored tuberous electroreceptor pores. First five lateral-line pores prominently visible against dark brown scaleless region behind head. Subdermal supratemporal lateral line canal visible externally as short, pale, irregularly-shaped lines. Pectoral fin hyaline at base, becoming dark over most of length. Distal margin of anal fin dark brown to black. Caudal fin uniformly dark, darker than caudal peduncle. Color of alcohol-preserved specimens similar to in life, but with pink and white hues replaced by pale yellow or cream.</p><p>Electric organ discharge. The ht-EOD comprises a wave-type waveform (Fig. 12A) with two high-energy positive components and one low-energy negative component in each cycle, with five crossings of 0 V. The mid portion of the cycle contains a brief period (» 0.5 V) during which voltage is approximately constant and only slightly below 0 V. The fundamental frequency is 0.942 kHz. The power spectral density computed exhibits a harmonic content (Fig. 12B), typical of wave-type ht-EODs, with the peak power frequency shifted from the dominant frequency to the first harmonic at 1.994 kHz (twice the dominant frequency). The shifting of peak power to the first harmonic is caused by the short-period dominant positive component in each ht-EOD cycle.</p><p>Ecology. Of the 59 specimens of Melanosternarchus amaru examined in this description, the majority (52) were collected from blackwater rivers. Six were collected from whitewater, and one from a clearwater river. This distribution suggests that this species exhibits a habitat preference for black or low-conductivity waters. The three specimens from the main channel of the Amazon were collected very near the mouth of the Rio Tapajós, a site with substantial clearwater input. Two specimens were taken from the lower Rio Purus, but the lower reaches of this river are known to have lower conductivity and suspended matter than other large, whitewater tributaries or the main channel of the Amazon (Gibbs, 1967; Ríos-Villamizar et al., 2016). One specimen was taken from the lower Rio Japurá. The Rio Japurá is a hybrid whitewater-blackwater river below its confluence with the Paraná Aranapú (a major channel which transports water from the Rio Amazonas to the Japurá). Extensive benthic sampling of the whitewater Amazon River near Iquitos and Tefé during both high and low water has not produced any specimens of M. amaru .</p><p>Little is known about the feeding habits of Melanosternarchus . Gut-content analysis of six specimens revealed a majority (4/6) to contain unidentified insect larvae. Beetle larvae (Coleoptera) and caddisfly larvae (Trichoptera) were each present in half of the stomachs, while trichopteran pupae were found in two stomachs. Larval mayflies (Ephemeroptera), stoneflies (Plecoptera), and chironomid midges were each found in only a single specimen. Additionally, the stomach of the largest specimen of M. amaru examined in this description contained scales and fin rays from the severed and swallowed caudal fin of another apteronotid electric fish.</p><p>Distribution. The collection localities for this species are summarized in Fig. 13. The majority of samples of this species were collected from the Rio Nanay near Iquitos (see Fig. 14) in the Maynas district of Loreto, Peru, but its range is extensive throughout the Amazon basin. Within Amazonas, Brazil, a single specimen was collected from the mouth of the Rio Japurá near Tefé. One lot (n=2) was collected from the Rio Purus, about 40 km upstream from its mouth. Several specimens were collected from the Rio Negro from as far as 50 km above the mouth of the Rio Branco, from the vicinity of São Francisco de Assis, and from the river’s confluence with the Amazon at Manaus. Within Pará, Brazil, two lots were collected from the Amazon River near the mouth of the Tapajós near Santarém and one specimen was captured from near the mouth of the Rio Xingu at Porto de Moz.</p><p>Etymology. The species name is from the Quechuan amaru, a mythical serpent, referring to the snakelike shape of this fish. A noun in apposition.</p><p>Phylogenetic relationships. Our maximum likelihood phylogram (Fig. 15) places Melanosternarchus as sister to Compsaraia, and also places the clade Compsaraia + Melanosternarchus as sister to Pariosternarchus Albert &amp; Crampton. This topology indicates that Sternarchogiton porcinum Eigenmann &amp; Allen is the sister to these three genera, but this relationship has a low bootstrap value of 41. This tree also shows Sternarchella Eigenmann to be sister to Sternarchogiton nattereri Steindachner and S. labiatus de Santana &amp; Crampton, with a bootstrap value of 40. Sternarchogiton preto de Santana &amp; Crampton is well-supported as the sister to all other Navajini.</p></div>	https://treatment.plazi.org/id/03AF5047FFA0A335FF77FD5284415D43	Public Domain	No known copyright restrictions apply. See Agosti, D., Egloff, W., 2009. Taxonomic information exchange and copyright: the Plazi approach. BMC Research Notes 2009, 2:53 for further explanation.		MagnoliaPress via Plazi	Bernt, Maxwell J.;Crampton, William G. R.;Orfinger, Alexander B.;Albert, James S.	Bernt, Maxwell J., Crampton, William G. R., Orfinger, Alexander B., Albert, James S. (2018): Melanosternarchus amaru, a new genus and species of electric ghost knifefish (Gymnotiformes: Apteronotidae) from the Amazon Basin. Zootaxa 4378 (4): 451-479, DOI: 10.11646/zootaxa.4378.4.1
