European Journal of Taxonomy 672: 1–18 ISSN 2118-9773 https://doi.org/10.5852/ejt.2020.672 www.europeanjournaloftaxonomy.eu 2020 · Dierickx K. & Snoeks J. This work is licensed under a Creative Commons Attribution Licence (CC BY 4.0). R e s e a r c h a r t i c l e urn:lsid:zoobank.org:pub:1B1D9E9B-A5B5-4E9A-976C-6409F81DAD76 1 Protomelas krampus, a new paedophagous cichlid from Lake Malawi (Teleostei, Cichlidae) Katrien DIERICKX 1,* & Jos SNOEKS 2 1,2 Ichthyology, Section Vertebrates, Department of Biology, Royal Museum for Central Africa, Tervuursesteenweg 13, 3080 Tervuren, Belgium. 1 BioArch, Department of Archaeology, University of York, England, United Kingdom. 2 Laboratory of Biodiversity and Evolutionary Genomics, Leuven University (KU Leuven), Charles Deberiotstraat 32, 3000 Leuven, Belgium. * Corresponding author: katrien.dierickx.icht@gmail.com 2 Email: jos.snoeks@africamuseum.be 1 urn:lsid:zoobank.org:author:390DD3DC-A240-4359-8643-C76FFCA68C4F 2 urn:lsid:zoobank.org:author:8841919C-2A14-4DEB-9CC4-69E3C8CA3295 Abstract. A new paedophagous species of Protomelas, P. krampus sp. nov., is described from Lake Malawi. It has been found in Lukoma Bay in Tanzania, near Mara Point in Mozambique, and at Otter Point, Chizumulu, the Likoma Islands and Mazinzi Reef in Malawi. This species is placed in the genus Protomelas based on its melanin pattern, which comprises a continuous midlateral stripe. A morphometric study was done to compare this species with its congeners and similar species of Hemitaeniochromis and Caprichromis. It differs from most congeners by having only one inner tooth row. Furthermore, P. krampus sp. nov. differs from P. insignis, P. spilopterus, H. brachyrhynchus, H. urotaenia, Caprichromis liemi and C. orthognathus by its shorter premaxillary pedicel, shorter prepectoral distances and dentition. It also differs largely in its melanin pattern from the paedophagous species C. liemi, C. orthognathus, Diplotaxodon greenwoodi and Naevochromis chrysogaster, as well as H. brachyrhynchus and H. urotaenia. Protomelas krampus sp. nov. has been observed to ram mouth-brooding cichlids from above to feed on their eggs or larvae. Keywords. Cichliformes, East Africa, mouth-brooding cichlids, Mozambique, trophic ecology. Dierickx K. & Snoeks J. 2020. Protomelas krampus, a new paedophagous cichlid from Lake Malawi (Teleostei, Cichlidae). European Journal of Taxonomy 672: 1–18. https://doi.org/10.5852/ejt.2020.672 Introduction Lake Malawi is home to about 800 to 1000 species of endemic cichlids (Snoeks 2000; Konings 2016). Because of their explosive speciation, species can be difficult to delineate and many species complexes and genera still need to be taxonomically resolved. In Lake Malawi, haplochromines constitute the major part of the cichlids. The endemic genus Protomelas Eccles &Trewavas, 1989 currently encompasses 14 to 16 valid species (Konings 2016; Froese & Pauly https://doi.org/10.5852/ejt.2020.672 http://www.europeanjournaloftaxonomy.eu/index.php/ejt/index https://creativecommons.org/licences/by/4.0/ http://zoobank.org/urn:lsid:zoobank.org:pub:1B1D9E9B-A5B5-4E9A-976C-6409F81DAD76 mailto:katrien.dierickx.icht%40gmail.com?subject= mailto:jos.snoeks%40africamuseum.be?subject= http://zoobank.org/urn:lsid:zoobank.org:author:390DD3DC-A240-4359-8643-C76FFCA68C4F http://zoobank.org/urn:lsid:zoobank.org:author:8841919C-2A14-4DEB-9CC4-69E3C8CA3295 https://doi.org/10.5852/ejt.2020.672 European Journal of Taxonomy 672: 1–18 (2020) 2 2019; Fricke et al. 2020). The genus is characterized by a typical melanin pattern with a well-developed continuous midlateral band from one eye length behind the opercle to the caudal fin and a dorsolateral band that may be spotted. Jaws are short and the length of the premaxillary pedicel is less than one third that of the head. Representatives of this genus have bicuspid anterior outer teeth that may be replaced by unicuspid teeth in adults; posterior outer teeth are simple (Eccles & Trewavas 1989). One species, Haplochromis urotaenia Regan, 1922, was placed in a newly described genus, Hemitaeniochromis Eccles & Trewavas, 1989, based on its melanin pattern having a typical discontinuous midlateral band (Eccles & Trewavas 1989). For a long time, it remained the sole species within this genus. Several undescribed species were attributed to the genus and later Protomelas spilopterus (Trewavas, 1935) was transferred by some authors to Hemitaeniochromis (see, e.g., Turner 1996; Snoeks & Hanssens 2004; Oliver 2012; Konings 2016). In addition, Oliver (2012) described a new species based on two specimens with a similar melanin pattern, H. brachyrhynchus Oliver, 2012. There is, however, major confusion on the precise delimitation of the genera Protomelas and Hemitaeniochromis (Snoeks & Hanssens 2004; Oliver 2012). Already in 1983, McKaye & Kocher observed an undescribed paedophagous species near Otter Point, Lake Malawi. This species seemed to differ from Caprichromis orthognathus (Trewavas, 1935) by its melanin pattern and behaviour (McKaye & Kocher 1983). Eccles & Trewavas (1989) suggested that this undescribed cichlid might be P. spilopterus, which is a suspected paedophage based on the resemblance of the jaws and pharyngeal teeth with those of known paedophagous species in Lake Victoria. Based on its head shape and behaviour, as observed by Konings (1989, 2016), it seems, however, to be an undescribed species, which was referred to as Protomelas sp. ‘paedophage’ and later Hemitaeniochromis sp. ‘paedophage’ (see, e.g., Konings 1989, 2016). Snoeks & Hanssens (2004) also mentioned a possibly paedophagous species, Protomelas sp. ‘paedophage’, stating that this may be the same species as observed by Konings (1989). These authors placed the only two available specimens in the genus Protomelas because of its continuous midlateral stripe. McKaye & Kocher (1983) noted that paedophagous species, i.e., Caprichromis liemi (McKaye & Mackenzie, 1982) and C. orthognathus, may change colour depending on their prey species. Therefore, as Turner (1996) already noted, it is not possible to rule out that this undescribed species may be conspecific to either of the species in Caprichromis Eccles & Trewavas, 1989 or congeneric based solely on its melanin pattern. A morphological analysis was needed to compare this undescribed paedophagous species with similar taxa. Three confirmed paedophagous species have currently been described from Lake Malawi. Protomelas spilopterus has short, oblique jaws with thick gums and one or two inner tooth rows. Both Caprichromis liemi and C. orthognathus have a melanin pattern with a diagonal stripe running from the nape to the base of the caudal fin. The teeth on the lower jaw are embedded in thick gums. Especially C. orthognathus has a steeply inclined mouth (Eccles & Trewavas 1989; Konings 2016). In addition to P. spilopterus, C. liemi and C. orthognathus, two more species are suspected of having a paedophagous diet (Stauffer & McKaye 1986; Eccles & Trewavas 1989). Diplotaxodon greenwoodi Stauffer & McKaye, 1986 is a widespread deep-water species. The genus Diplotaxodon Trewavas, 1935 is characterized by the lack of distinct markings such as bars or spots on the body. Its lower jaw protrudes and the teeth on the lower jaw are embedded in thick gums. Diplotaxodon greenwoodi has a steeply inclined mouth, large eyes and one to three inner tooth rows (Stauffer & McKaye 1986; Trewavas & Eccles 1989; Snoeks 2004). Naevochromis chrysogaster (Trewavas, 1935) has a suprapectoral spot, a midlateral spot covering the lateral line, a supranal spot positioned between the lateral lines and a precaudal spot. The chin is prominent and thick. It has a broad mouth and fleshy lips that embed the teeth. There is one inner row of teeth in the upper and two in the lower jaw (Eccles & Trewavas 1989; Konings 2016). As is clear from various discussions (e.g., Eccles & Trewavas 1989; Snoeks 2004; Oliver 2012; Konings 2016) there is still some confusion regarding the classification of species within the genera Protomelas DIERICKX K. & SNOEKS J., A new paedophagous cichlid 3 and Hemitaeniochromis. In this study, we follow the classification provided by Eccles & Trewavas (1989), expanded by Oliver (2012). It is, however, clear that a taxonomical revision of the species in the genera Protomelas and Hemitaeniochromis is necessary. For now, we suggest including the newly described paedophagous species in the genus Protomelas based on its continuous midlateral band and short jaws, following Snoeks & Hanssens (2004). We await a further revision of the complex for a final generic allocation. Below, the species that is new to science is described as Protomelas krampus sp. nov. Material and methods In total, 44 specimens of Protomelas, Hemitaeniochromis and Caprichromis in the collections at the Royal Museum of Central Africa, Tervuren, and the Natural History Museum, London, were examined: five specimens of C. liemi, five of C. orthognathus, one of H. brachyrhynchus, five of H. urotaenia, eleven of H. sp. ‘insignis like’ (sensu Snoeks & Hanssens 2004), four of P. insignis, two of P. krampus sp. nov. and eleven of P. spilopterus. The measurements and counts performed here follow Snoeks (2004). Two additional measurements, as described by Oliver (2012), were taken: the snout width and belly length. Also, the gape inclination, the angle between the midlateral line and the anteriormost tip of the upper jaw, was measured. In total, 21 length measurements, 13 counts (including the number of vertebrae via X-rays), one angle (gape inclination) (see Tables 4 and 5) and some qualitative observations on the body and head shape, dentition, and the colour pattern in alcohol were made. Principal component analysis (PCA) was performed in Past3 (Hammer et al. 2001) to explore the multivariate data set. Measurements were log-transformed and the covariance matrix was used. When using log-transformed measurements, the individual loadings of all variables on the first principal component (PC 1) are of the same magnitude and sign, and PC 1 can therefore be regarded as a proxy for multivariate size (Jolicoeur 1963; Snoeks 2004; Van Steenberge et al. 2015). The correlation matrix was used for the raw meristic data. Repositories MRAC = Musée royal de l’Afrique centrale, Tervuren, Belgium (used traditionally for collections of the Royal Museum of Central Africa) BMNH = British Museum of Natural History, London, UK (used traditionally for collections of the Natural History Museum) Abbreviations used in text HL = head length PC = principal component PCA = principal component analysis SL = standard length Results Comparative morphometrics A PCA on 21 log-transformed measurements including all specimens showed a clear separation of Protomelas krampus sp. nov. from all other species in the negative part of PC 2 on the second principal axis (Fig. 1). In general morphology, it seems to be most similar to C. orthognathus. The most important loadings on PC 2 are of the premaxillary pedicel length, cheek depth, belly length, caudal peduncle length, interorbital width and dorsal fin base (Table 1). In a comparison with both species of Caprichromis, P. krampus sp. nov. remains clearly separated on the third principal axis (Fig. 2). The most important European Journal of Taxonomy 672: 1–18 (2020) 4 Table 1. Loadings of PC 1, PC 2 and PC 3 of the principal component analysis of 21 log-transformed measurements of all specimens in the analysis. Fig. 1. Scatter plot of PC 1 against PC 2 for a principal component analysis of 21 log-transformed measurements of all specimens studied (n = 44). Protomelas krampus sp. nov. = blue dot; Hemitaenio- chromis brachyrhynchus Oliver, 2012 = purple square; H. urotaenia (Regan, 1922) = green square; Hemitaeniochromis sp. ‘insignis like’ = red triangle; P. spilopterus (Trewavas, 1935) = grey inverted triangle; P. insignis (Trewavas, 1935) = golden diamond; Caprichromis liemi (McKaye & Mackenzie, 1982) = light brown dash; C. orthognathus (Trewavas, 1935) = dark brown rectangle. Measurement PC1 PC 2 PC 3 Standard length 0.21 -0.16 0.03 Body depth 0.23 -0.05 0.18 Prepectoral distance 0.20 0.08 -0.05 Predorsal distance 0.21 0.16 0.01 Preventral distance 0.21 -0.05 0.05 Preanal distance 0.21 -0.11 -0.02 Dorsal fin base length 0.22 -0.22 0.07 Anal fin base length 0.20 -0.18 0.05 Caudal peduncle length 0.22 -0.25 0.12 Caudal peduncle depth 0.24 -0.17 0.11 Belly length 0.21 -0.27 -0.08 Head width 0.22 0.16 0.29 Head length 0.20 0.10 -0.10 Premaxillary pedicel length 0.18 0.61 -0.14 Snout length 0.24 0.19 -0.31 Lacrimal depth 0.26 0.14 -0.55 Cheek depth 0.26 -0.33 -0.19 Eye diameter 0.14 0.19 0.33 Inter orbital width 0.24 0.24 0.48 Snout width 0.24 0.13 0.07 Lower jaw length 0.22 -0.04 -0.17 % variance 90.77% 3.04% 2.13% DIERICKX K. & SNOEKS J., A new paedophagous cichlid 5 Table 2. Loadings of PC 1, PC 2 and PC 3 of the principal component analysis of 21 log-transformed measurements of both species of Caprichromis Eccles & Trewavas, 1989 and P. krampus sp. nov. Measurement PC1 PC 2 PC 3 Standard length 0.21 -0.10 -0.12 Body depth 0.20 0.08 -0.21 Prepectoral distance 0.20 0.17 -0.04 Predorsal distance 0.20 0.19 0.07 Preventral distance 0.22 0.04 -0.24 Preanal distance 0.23 0.01 -0.09 Dorsal fin base length 0.22 -0.06 -0.26 Anal fin base length 0.19 -0.08 -0.08 Caudal peduncle length 0.23 -0.32 0.21 Caudal peduncle depth 0.25 -0.15 0.02 Belly length 0.22 -0.20 0.10 Head width 0.22 -0.11 0.29 Head length 0.20 0.13 -0.09 Premaxillary pedicel length 0.15 0.61 0.52 Snout length 0.23 0.35 -0.34 Lacrimal depth 0.22 0.33 -0.16 Cheek depth 0.30 -0.29 -0.10 Eye diameter 0.15 -0.10 -0.04 Inter orbital width 0.25 -0.13 0.39 Snout width 0.23 -0.03 0.26 Lower jaw length 0.22 0.02 -0.00 % variance 86.45% 9.34% 1.90% Fig. 2. Scatter plot of PC 1 against PC 3 for a principal component analysis of 21 log-transformed measurements of Protomelas krampus sp. nov., Caprichromis liemi (McKaye & Mackenzie, 1982) and C. orthognathus (Trewavas, 1935) (n = 12). P. krampus sp. nov. = blue dot; C. liemi = light brown dash; C. orthognathus = dark brown rectangle. European Journal of Taxonomy 672: 1–18 (2020) 6 loadings on PC 3 are for the premaxillary pedicel length, the interorbital width, the snout length, the head width, the dorsal fin base and the snout width (Table 2). In a PCA on the raw meristics, the picture was less clear. Still, P. krampus sp. nov. was separated from all other species (Fig. 3), mostly on PC 1. The most important loadings on PC 1 are of the number of vertebrae, the number of both upper and lower jaw teeth, the number of longitudinal line scales, the Table 3. Loadings of PC 1 and PC 2 of the principal component analysis of 13 counts. Counts PC 1 PC 2 Longitudinal line 0.33 -0.37 Upper lateral line 0.26 -0.06 Lower lateral line 0.24 -0.37 Lower gill rakers 0.05 0.08 Upper gill rakers 0.08 0.09 Dorsal fin spines 0.31 -0.20 Dorsal fin rays 0.25 0.57 Anal fin rays 0.29 0.45 Pectoral fin rays 0.07 -0.26 Vertebrae 0.43 -0.05 Inner teeth rows 0.22 0.05 Upper teeth 0.40 -0.10 Lower teeth 0.34 0.22 % variance 29.05% 12.70% Fig. 3. Scatter plot of PC 1 against PC 2 for a principal component analysis of 13 counts of all specimens studied (n = 44). Protomelas krampus sp. nov. = blue dot; Hemitaeniochromis brachyrhynchus Oliver, 2012 = purple square; H. urotaenia (Regan, 1922) = green square; Hemitaeniochromis sp. ‘insignis like’ = red triangle; P. spilopterus (Trewavas, 1935) = grey inverted triangle; P. insignis (Trewavas, 1935) = golden diamond; Caprichromis liemi (McKaye & Mackenzie, 1982) = light brown dash; C. orthognathus (Trewavas, 1935) = dark brown rectangle. DIERICKX K. & SNOEKS J., A new paedophagous cichlid 7 number of dorsal fin spines and the number of anal fin rays. On PC 2, the highest loadings are the number of dorsal fin rays, the number of anal fin rays, the number of scales on the lower lateral line, the number of longitudinal line scales, the number of pectoral fin rays and the number of outer lower jaw teeth (Table 3). Taxonomy Phylum Chordata Haeckel, 1874 Class Actinopterygii Klein, 1885 Order Cichliformes Betancur et al., 2013 Family Cichlidae Bonaparte, 1840 Subfamily Pseudocrenilabrinae Fowler, 1934 Tribe Haplochromini Poll, 1986 Genus Protomelas Eccles & Trewavas, 1989 Protomelas Eccles & Trewavas, 1989: 40 (type species: Chromis kirkii Günther, 1894, by original designation). Protomelas krampus sp. nov. urn:lsid:zoobank.org:act:5C1913C2-E6C9-43CD-BB1C-5522DFC60B8C Figs 4–5; Tables 4–5 Diagnosis Protomelas krampus sp. nov. differs from most species of Protomelas, i.e., P. annectens (Regan, 1922), P. fenestratus (Trewavas, 1935), P. kirkii (Günther, 1894), P. labridens (Trewavas, 1935), P. macrodon Eccles, 1989, P. marginatus (Trewavas, 1935), P. pleurotaenia (Boulenger, 1901), P. similis (Regan, 1922), P. spilonotus (Trewavas, 1935), P. taeniolatus (Trewavas, 1935), P. triaenodon (Trewavas, 1935) and P. virgatus (Trewavas, 1935), by having only one inner tooth row, whereas the other species have two rows. It can be distinguished from P. spilopterus by a shorter premaxillary pedicel (17.0–19.2 vs 21.8–28.4% HL), a larger gape inclination (70–80 vs 40–60°), a shallower body (33.3–34.3 vs 36.0–42.8% SL), a smaller predorsal (27.4–29.1 vs 33.4–37.4% SL) and prepectoral distance (29.4–29.8 vs 31.8–40.0% SL), a shorter and more slender head (length 27.8–29.2 vs 30.4–34.6% SL and width 39.3–40.3 vs 41.4– 50.7% HL, respectively), and a smaller interorbital width (22.9–23.4 vs 25.0–33.6% HL). In addition, P. krampus sp. nov. has more gill rakers on the outer epibranchial (further mentioned as upper gill rakers) than P. spilopterus (5 vs 3–4) and more vertebrae (31–32 vs 29). The inner teeth are tricuspid in P. krampus sp. nov. while mixed unicuspid/tricuspid or unicuspid in P. spilopterus. The outer teeth of the lower jaw of P. krampus sp. nov. are oriented straight up, whereas those of P. spilopterus are angled forward, except for in one specimen which has slightly inwards curved teeth. Protomelas krampus sp. nov. differs from P. insignis by a shorter premaxillary pedicel (17.0–19.2 vs 27.9–30.0% HL), a deeper cheek (31.6–40.2 vs 23.2–28.5% HL), the larger gape inclination (70–80 vs 30°), a smaller predorsal (27.4–29.1 vs 34.2–35.9% SL) and prepectoral distance (29.4–29.8 vs 32.7– 35.4% SL), a shorter and more slender head (length 27.8–29.2 vs 31.6–34.3% SL and width 39.3– 40.3 vs 41.3–44.8% HL, respectively), a shallower lacrimal (19.6–20.4 vs 21.4–22.4% HL), a smaller interorbital width (22.9–23.4 vs 26.9–32.8% HL), and a longer lower jaw (37.7–38.8 vs 31.2–37.3% HL). The upper jaw has fewer outer teeth in P. krampus sp. nov. than in P. insignis (37–40 vs 43–50). Outer lower jaw teeth are straight in P. krampus sp. nov. but curved inwards in P. insignis. http://zoobank.org/urn:lsid:zoobank.org:act:5C1913C2-E6C9-43CD-BB1C-5522DFC60B8C European Journal of Taxonomy 672: 1–18 (2020) 8 Protomelas krampus sp. nov. differs from the undescribed species mentioned by Snoeks & Hanssens (2004) as Hemitaeniochromis. sp. ‘insignis like’ by a shorter premaxillary pedicel (17.0–19.2 vs 24.7– 30.7% HL), a deeper cheek depth (31.6–40.2 vs 22.5–28.8% HL), a larger gape inclination (70–80 vs 40–60°), a shorter predorsal (27.4–29.1 vs 33.5–38.3% SL) and prepectoral distance (29.4–29.8 vs 31.1–38.1% SL), a shorter and more slender head (length 27.8–29.2 vs 31.3–34.5% SL and width 39.3–40.3 vs 40.8–46.8% HL, respectively), and a longer lower jaw (37.7–38.8 vs 28.9–35.0% HL). Protomelas krampus sp. nov. has more gill rakers on the outer epibranchial than H. sp. ‘insignis like’ (5 vs 3–4). There are more dorsal fin rays in P. krampus sp. nov. than in H. sp. ‘insignis like’ (11–12 vs 9–10). The outer teeth of the lower jaw of P. krampus sp. nov. are oriented straight up, whereas those of H. sp. ‘insignis like’ are angled forward. Protomelas krampus sp. nov. differs from both species of the genus Hemitaeniochromis by its continuous midlateral stripe, which places it in Protomelas, whereas H. urotaenia and H. brachyrhynchus have an anteriorly spotted stripe. In addition, P. krampus sp. nov. differs from H. urotaenia by a shorter premaxillary pedicel (17.0–19.2 vs 27.5–28.9% HL), a deeper cheek (31.6–40.2 vs 27.3–30.6% HL), a larger gape inclination (70–80 vs 30–50°), a longer dorsal fin base (53.6–58.3 vs 49.3–50.5% SL), a shorter predorsal (27.4–29.1 vs 37.0–38.7% SL) and prepectoral distance (29.4–29.8 vs 35.2–36.7% SL), a shorter and more slender head (length 27.8–29.2 vs 34.9–37.3% SL and width 39.3–40.3 vs 40.5–42.5% HL respectively), and a shallower lacrimal (19.6–20.4 vs 22.7–23.3% HL). Protomelas krampus sp. nov. has more vertebrae (31–32 vs 30), more gill rakers on the outer epibranchial (5 vs 2–4) and more dorsal fin rays (11–12 vs 9–10) than H. urotaenia. Protomelas krampus sp. nov. has only one inner tooth row with tricuspid teeth, whereas H. urotaenia has two rows of mostly unicuspid teeth. The outer lower jaw teeth are straight in P. krampus sp. nov., whereas they are curved inwards in H. urotaenia. Protomelas krampus sp. nov. differs from H. brachyrhynchus by a shorter premaxillary pedicel (17.0– 19.2 vs 27.1% HL), a deeper cheek (31.6–40.2 vs 21.4% HL), a larger gape inclination (70–80 vs 45°), a shallower body (33.3–34.3 vs 37.7% SL), a shorter predorsal (27.4–29.1 vs 37.8% SL), preventral (39.0–44.4 vs 46.1% SL) and prepectoral distance (29.4–29.8 vs 37.0% SL), a shorter anal fin base length (18.3–18.8 vs 21.2% SL), a shorter and more slender head (27.8–29.2 vs 35.3% SL and 39.3–40.3 vs 43.8% HL, respectively), a longer snout (33.3–34.2 vs 30.1% HL), a deeper lacrimal (19.6–20.4 vs 17.2% HL), a smaller eye (22.5–27.0 vs 32.2% HL), and a longer lower jaw (37.7–38.8 vs 32.9% HL). Protomelas krampus sp. nov. has more vertebrae (31–32 vs 30), upper gill rakers (5 vs 4) and dorsal fin rays (11–12 vs 10) than H. brachyrhynchus. The outer teeth of the lower jaw of P. krampus sp. nov. are oriented straight up, whereas those of H. brachyrhynchus are angled forward and slightly outwards. Protomelas krampus sp. nov. differs from the paedophagous species of the genus Caprichromis by its melanin pattern: it has a midlateral band from behind the opercle to the base of the caudal fin, whereas species of Caprichromis have a diagonal stripe from the nape to the base of the caudal fin. Protomelas krampus sp. nov. further differs from C. orthognathus by a shorter premaxillary pedicel (17.0–19.2 vs 21.9–25.4% HL) and a shorter prepectoral distance (29.4–29.8 vs 30.2–33.4% SL). There are more soft dorsal fin rays in P. krampus sp. nov. than in C. orthognathus (11–12 vs 10) and more gill rakers on the outer epibranchial (5 vs 3–4). Protomelas krampus sp. nov. has fewer outer teeth in the lower jaw (31–36 vs 42–50). Protomelas krampus sp. nov. differs from C. liemi by a shorter premaxillary pedicel (17.0–19.2 vs 24.7–28.0% HL), a deeper cheek (31.6–40.2 vs 25.5–29.5% HL), a larger gape inclination (70–80 vs DIERICKX K. & SNOEKS J., A new paedophagous cichlid 9 30–60°), a shallower body (33.3–34.3 vs 36.1–38.6% SL), shorter predorsal (27.4–29.1 vs 35.0–36.7% SL) and prepectoral distances (29.4–29.8 vs 34.2–36.5% SL), a shorter and wider head (length 27.8– 29.2 vs 31.9–33.6% SL and width 39.3–40.3 vs 35.9–38.2% HL, respectively), and a shallower lacrimal (19.6–20.4 vs 20.8–23.9% HL). There are fewer scales along the upper lateral line in P. krampus sp. nov. than in C. liemi (20–23 vs 25–27). Protomelas krampus sp. nov. has fewer outer teeth in the upper jaw (37–40 vs 44–47) and lower jaw (31–36 vs 44–59) than C. liemi. Protomelas krampus sp. nov. differs from Diplotaxodon greenwoodi by the lack of a melanin pattern in the latter species. It has isognathous jaws, whereas D. greenwoodi has a protruding lower jaw. Protomelas krampus sp. nov. differs from Naevochromis chrysogaster by its melanin pattern, which consists of three large spots on the lateral sides in the latter instead of a continuous midlateral line. It has a more strongly inclined gape than N. chrysogaster. Protomelas krampus sp. nov. has only one inner tooth row on the lower jaw, whereas N. chrysogaster has two. Etymology The specific name, ʻkrampusʼ, is a noun in apposition and was chosen in reference to the European folklore character Krampus. This demon puts naughty children in a bag and takes them away, which is reminiscent of a paedophagous behaviour. The goat-like appearance of Krampus also implicitly refers to the head-butting behaviour of the species. The same implicit reference to this behaviour is also found in the genus name Caprichromis of other paedophagous species of Lake Malawi. Material examined Holotype TANZANIA • ♀; Lake Malawi, Lukoma Bay; 11°22.50′ S, 34°52.00′ E; 11 Jan. 1998; SADC/GEF Taxonomy team leg.; 116.1 mm SL; MRAC 99-041-P-4768. Paratype MOZAMBIQUE • 1 ♂; Lake Malawi, Mara Rocks; 12°11.34′ S, 34°41.73′ E; 22 May 1998; SADC/ GEF Taxonomy team leg.; 181.1 mm SL; MRAC 99-041-P-4767. Comparative material Hemitaeniochromis brachyrhynchus (Oliver, 2012) MALAWI • 1 paratype; Lake Malawi, Nkhata Bay, south bay; 11°36.22′ S, 34°19.16′ E; 27 Sep. 1997; SADC/GEF Taxonomy team leg.; 81.6 mm SL; MRAC 99-041-P-1746. Hemitaeniochromis urotaenia (Regan, 1922) MALAWI • 2 specs; Lake Malawi, Kande Bay, S of Bandawe; 11°56.47′ S, 34°09.41′ E; 3 Jun. 1997; SADC/GEF Taxonomy team leg.; 142.2–182.7 mm SL; MRAC 99-041-P-1738-1739 • 3 specs [of 5 in lot]; Lake Malawi, Nkhotakota; 12°52.95′ S, 34°19.33′ E; 22 Sep. 1997; SADC/GEF Taxonomy team leg.; 87.8–119.0 mm SL; MRAC 99-041-P-1741-1745. Hemitaeniochromis sp. “insignis like” MALAWI • 3 specs; Lake Malawi, Chipoka to Makanjila, SW arm and SE arm; 14°00.62′ S, 34°37.29′ E; 18 Nov. 1997; SADC/GEF Taxonomy team leg.; 122.0–148.5 mm SL; MRAC 99-041-P-1747-1749 • 1 spec.; Lake Malawi, Nkhotakota; 12°52.95′ S, 34°19.34′ E; 22 Sep. 1997; SADC/GEF Taxonomy team leg.; 76.9 mm SL; MRAC 99-041-P-1750 • 1 spec.; Lake Malawi, Senga Bay; 13°45.13′ S, 34°29.22′ E; 8 Jun. 1997; SADC/GEF Taxonomy team leg.; 145.2 mm SL; MRAC 99-041-P-1773 • 2 specs; Lake Malawi, Chipoka to Makanjila, SW arm and SE arm; 13°52.45′ S, 34°54.74′ E; 9 Oct. 1997; SADC/ European Journal of Taxonomy 672: 1–18 (2020) 10 GEF Taxonomy team leg.; 139.7–172.4 mm SL; MRAC 99-041-P-2625-2626 • 1 spec.; Lake Malawi, Chipoka to Makanjila, SW arm and SE arm; 13°57.77′ S, 34°43.37′ E; 10 Oct. 1997; SADC/GEF Taxonomy team leg.; 142.7 mm SL; MRAC 99-041-P-2627 • 1 spec.; Lake Malawi, SW arm; 14°07.00′ S, 34°44.30′ E; 18 Dec. 1996; SADC/GEF Taxonomy team leg.; 169.0 mm SL; MRAC 99-041-P-1755. MOZAMBIQUE • 1 spec.; Lake Malawi, Chiwanga Bay; 12°39.03′ S, 34°46.56′ E; 11 Apr. 1998; SADC/GEF Taxonomy team leg.; 111.9 mm SL; MRAC 99-041-P-1753 • 1 spec.; Lake Malawi, Chiwanga Bay; 12°39.03′ S, 34°46.56′ E; 11 Apr. 1998; SADC/GEF Taxonomy team leg.; 117.8 mm SL; MRAC 99-041-P-1754. Protomelas spilopterus (Trewavas, 1935) MALAWI • lectotype, 3 paralectotypes; Lake Malawi, South End; 1925; 147.1–166.0 mm SL; BMNH 1935.6.14.644-647 • 2 paralectotypes [of 3 in lot]; Lake Malawi, Mwaya; 1925; 149.1–153.4 mm SL; BMNH 1935.6.14.649-651 (2 of 3) • 5 paralectotypes [of 6 in lot]; Lake Malawi, Monkey Bay; 1925; 85.5–160.4 mm SL; BMNH 1935.6.14.652-657. Protomelas insignis (Trewavas, 1935) MALAWI • lectotype, 3 paralectotypes; Lake Malawi, Monkey Bay; 1925; 81.7–161.0 mm SL; BMNH 1935.6.14.839-843. Caprichromis liemi (McKaye & Mackenzie, 1982) MALAWI • 1 spec.; Lake Malawi, Chipoka to Makanjila, SW arm and SE arm; 14°00.62′ S, 34°37.29′ E; 18 Nov. 1997; SADC/GEF Taxonomy team leg.; 129.2 mm SL; MRAC 99-041-P-2647. MOZAMBIQUE • 1 spec.; Lake Malawi, Chilola Bay; 12°06.45′ S, 34°46.79′ E; 7 Apr. 1998; SADC/ GEF Taxonomy team leg.; 117.9 mm SL; MRAC 99-041-P-2648 • 1 spec.; Lake Malawi, Tchulutcha Reef, Metangula; 12°42.19′ S, 34°47.46′ E; 25 May 1998; SADC/GEF Taxonomy team leg.; 173.2 mm SL; MRAC 99-041-P-2649 • 2 specs; Lake Malawi, Namisse, S of Cobue; 12°10.08′ S, 34°42.97′ E; 24 May 1998; SADC/GEF Taxonomy team leg.; 103.2–144.4 mm SL; MRAC 99-041-P-5018-5019. Caprichromis orthognathus (Trewavas, 1935) MALAWI • 1 spec.; Lake Malawi, Mazinzi Bay, SE arm; 4 Sep. 1980; D.S.C. Lewis leg.; 146.7 mm SL; MRAC 81-02-P-33 • 1 spec.; Lake Malawi; 25 Jun. 1962; 154.1 mm SL; MRAC 191849. MOZAMBIQUE • 1 spec.; Lake Malawi, Chiwanga Bay; 12°38.52′ S, 34°46.37′ E; 10 Apr.1998; SADC/ GEF Taxonomy team leg.; 122.0 mm SL; MRAC 99-041-P-2644 • 2 specs; Lake Malawi, Chiwanga Bay; 12°38.81′ S, 34°46.68′ E; 10 Apr. 1998; SADC/GEF Taxonomy team leg.; 128.3–131.4 mm SL; MRAC 99-041-P-2645-2646. Diplotaxodon greenwoodi (Stauffer & McKaye, 1986) MALAWI • 1 spec.; Lake Malawi, Senga Bay; 13°45.25′ S, 34°40′30″ E; 8 Jun. 1997; SADC/GEF Taxonomy team leg.; MRAC 1999-041-P-10765 • 1 spec.; Lake Malawi, Chipoka to Makanjila, SW arm and SE arm; 13°57′46.19″ S, 34°43′22.19″ E; 10 Oct. 1997; SADC/GEF Taxonomy team leg.; MRAC 1999-041-P-10766. MOZAMBIQUE • 1 spec.; Lake Malawi, Chilola Bay, 2nd bay of Cobwe; 12°00′44.39″ S, 34°47′16.80″ E; 8 Apr. 1998; SADC/GEF Taxonomy team leg.; MRAC 1999-041-P-10768. TANZANIA • 1 spec.; Lake Malawi, Weismann Bay; 9°30′46.80″ S, 34°00′19.80″ E; 14 Jan. 1998; SADC/GEF Taxonomy team leg.; MRAC 1999-041-P-10767. DIERICKX K. & SNOEKS J., A new paedophagous cichlid 11 Naevochromis chrystogaster (Trewavas, 1935) MALAWI • 1 spec.; Lake Malawi, Mdoka; 10°19′00.01″ S, 34°12′00″ E; May 1989; A. Konings leg.; MRAC 1991-095-P-0037 • 1 spec.; Lake Malawi, Cape Ngombo near Makanjila Point; 13°44′07.19″ S, 34°51′16.20″ E; 13 Nov. 1997; SADC/GEF Taxonomy team leg.; MRAC 1999-041-P-8524. TANZANIA • 1 spec.; Lake Malawi, Lutara, N of bay; 10°25′57.61″ S, 34°33′33.59″ E; 11 Nov. 1998; SADC/GEF Taxonomy team leg.; MRAC 1999-041-P-5205. Description Based on holotype and one paratype (see Figs 4–5 and Tables 4–5). Qualitative observations are described in the context of Lake Malawi haplochromine cichlids as conducted by Snoeks (2004). Body. Moderately elongate. Head. Profile somewhat steep, clearly concave at eye level. Snout above upper jaw convex. Mouth very steep, vertically orientated with a gape inclination of 70–80°. Premaxillary pedicel small. Jaws Fig. 4. Photographs of preserved specimens of Protomelas krampus sp. nov. A. Holotype (RMCA 99- 041-P-4768). B. Paratype (RMCA 99-041-P-4767). Melanin pattern strongly faded. European Journal of Taxonomy 672: 1–18 (2020) 12 Ta bl e 4. M ea su re m en ts f or P ro to m el as k ra m pu s sp . n ov . ( ho lo ty pe a nd p ar at yp e) , c om pa re d w ith th e ra ng es a nd m ea ns o f th e ex am in ed s pe ci m en s of P . i ns ig ni s (T re w av as , 1 93 5) , H em ita en io ch ro m is s p. ‘ in si gn is li ke ’, P. s pi lo pt er us ( Tr ew av as , 1 93 5) , H em ita en io ch ro m is b ra ch yr hy nc hu s O liv er , 20 12 , H . u ro ta en ia (R eg an , 1 92 2) , C ap ri ch ro m is li em i ( M cK ay e & M ac ke nz ie , 1 98 2) a nd C . o rt ho gn at hu s (T re w av as , 1 93 5) . P. k ra m pu s sp . n ov . P. in si gn is H . s p. ‘i ns ig ni s lik e’ P. s pi lo pt er us H . b ra ch yr hy nc hu s H . u ro ta en ia C . o rt ho gn at hu s C . l ie m i H ol ot yp e P ar at yp e M or ph om et ri cs R an ge , m ea n (n = 4 ) R an ge , m ea n (n = 11 ) R an ge , m ea n (n = 11 ) (n = 1 ) R an ge , m ea n (n = 5 ) R an ge , m ea n (n = 4 ) R an ge , m ea n (n = 5 ) St an da rd le ng th (S L ) i n m m 11 6. 1 18 1. 1 81 .7 –1 61 .0 (1 28 .9 ) 76 .9 –1 72 .4 (1 35 .8 ) 85 .5 –1 66 .0 (1 37 .8 ) 81 .6 87 .8 –1 82 .7 (1 25 .6 ) 12 2. 0– 15 4. 1 (1 36 .5 ) 10 3. 2– 17 3. 2 (1 33 .6 ) G ap e in cl in at io n (i n de gr ee s) 70 80 30 (3 0) 35 –6 0 (4 7. 3) 40 –6 0 (4 5. 9) 45 30 –5 0 (4 1) 70 –9 0 (8 0. 5) 30 –6 0 (4 8) A s % SL : B od y de pt h 33 .3 34 .3 33 .8 –3 7. 0 (3 5. 6) 34 .2 –4 0. 3 (3 7. 2) 36 .0 –4 2. 8 (3 8. 9) 37 .7 31 .5 –3 5. 5 (3 3. 6) 32 .5 –3 4. 8 (3 3. 8) 36 .1 –3 8. 6 (3 7. 4) H ea d le ng th 27 .8 29 .2 31 .6 –3 4. 3 (3 2. 5) 31 .3 –3 4. 6 (3 3. 0) 30 .4 –3 4. 6 (3 2. 9) 35 .3 34 .9 –3 7. 3 (3 6. 1) 29 .3 –3 1. 1 (3 0. 3) 31 .9 –3 3. 6 (3 2. 8) Pr ep ec to ra l d is ta nc e 29 .4 29 .8 32 .7 –3 5. 4 (3 3. 7) 31 .1 –3 8. 1 (3 4. 5) 31 .8 –4 0. 0 (3 5. 3) 37 .0 35 .2 –3 6. 7 (3 6. 2) 30 .2 –3 3. 4 (3 2. 0) 34 .2 –3 6. 5 (3 5. 2) Pr ed or sa l d is ta nc e 29 .0 27 .4 34 .2 –3 5. 9 (3 4. 9) 33 .5 –3 8. 3 (3 5. 7) 33 .4 –3 7. 4 (3 6. 2) 37 .8 37 .0 –3 8. 7 (3 7. 6) 31 .3 –3 3. 4 (3 2. 5) 35 .0 –3 6. 7 (3 5. 6) Pr ev en tr al d is ta nc e 39 .0 44 .4 40 .1 –4 2. 9 (4 1. 7) 38 .6 –4 8. 3 (4 3. 6) 41 .2 –5 1. 0 (4 6. 0) 46 .1 41 .7 –4 5. 4 (4 3. 4) 39 .7 –4 4. 1 (4 2. 2) 42 .8 –4 8. 7 (4 4. 5) Pr ea na l d is ta nc e 62 .3 69 .8 67 .5 –7 0. 1 (6 8. 8) 63 .7 –7 2. 7 (6 9. 3) 64 .7 –7 2. 1 (6 9. 1) 70 .0 66 .0 –6 9. 9 (6 7. 7) 67 .2 –7 0. 3 (6 8. 4) 68 .5 –7 2. 6 (7 0. 7) D or sa l fi n ba se 53 .6 58 .3 52 .0 –5 8. 7 (5 6. 3) 50 .5 –5 6. 6 (5 3. 3) 49 .8 –5 7. 6 (5 4. 1) 54 .3 49 .3 –5 0. 5 (5 0. 1) 52 .9 –5 4. 3 (5 3. 7) 55 .3 –5 6. 6 (5 5. 7) A na l fi n ba se 18 .2 18 .8 17 .9 –1 9. 3 (1 8. 6) 16 .6 –2 0. 1 (1 8. 1) 17 .8 –2 0. 7 (1 9. 4) 21 .2 17 .4 –2 0. 2 (1 9. 0) 18 .4 –1 9. 3 (1 8. 9) 18 .3 –1 9. 9 (1 9. 2) C au da l p ed un cl e le ng th 17 .2 19 .6 17 .5 –1 7. 8 (1 7. 7) 15 .9 –1 9. 5 (1 8. 1) 17 .5 –1 9. 3 (1 8. 4) 15 .7 17 .0 –1 9. 4 (1 8. 2) 18 .5 –2 0. 9 (1 9. 4) 15 .4 –1 8. 1 (1 7. 0) C au da l p ed un cl e de pt h 11 .6 12 .6 12 .3 –1 3. 2 (1 2. 7) 11 .3 –1 3. 7 (1 2. 5) 11 .4 –1 4. 1 (1 2. 6) 12 .6 11 .3 –1 2. 8 (1 1. 9) 12 .3 –1 3. 2 (1 2. 6) 11 .2 –1 3. 4 (1 2. 2) B el ly le ng th 27 .8 29 .5 28 .3 –2 9. 8 (2 9. 2) 27 .3 –3 2. 3 (2 9. 7) 23 .4 –2 9. 0 (2 6. 1) 28 .5 26 .6 –2 8. 7 (2 7. 8) 29 .2 –3 2. 6 (3 0. 5) 24 .5 –3 1. 4 (2 8. 5) A s % H L : H ea d w id th 39 .3 40 .3 41 .3 –4 4. 8 (4 3. 4) 40 .8 –4 6. 8 (4 3. 2) 41 .4 –5 0. 7 (4 6. 6) 43 .8 40 .5 –4 2. 5 (4 1. 9) 40 .7 –4 5. 5 (4 3. 3) 35 .9 –3 8. 2 (3 7. 0) Pr em ax ill ar y pe di ce l l en gt h 19 .2 17 .0 27 .9 –3 0. 0 (2 9. 3) 24 .7 –3 0. 7 (2 9. 0) 21 .8 –2 8. 4 (2 6. 3) 27 .1 27 .5 –2 8. 9 (2 8. 0) 21 .9 –2 5. 4 (2 3. 7) 24 .7 –2 8. 0 (2 7. 0) Sn ou t l en gt h 34 .2 33 .3 32 .7 –3 9. 3 (3 6. 4) 30 .6 –3 6. 4 (3 3. 6) 30 .8 –3 7. 8 (3 3. 9) 30 .1 34 .1 –3 7. 5 (3 5. 6) 31 .4 –3 3. 7 (3 2. 2) 34 .8 –3 9. 6 (3 7. 2) L ac hr ym al d ep th 20 .4 19 .6 21 .4 –2 2. 4 (2 1. 9) 17 .4 –2 5. 3 (2 0. 6) 13 .6 –2 2. 7 (1 9. 0) 17 .2 22 .7 –2 3. 3 (2 3. 0) 18 .6 –2 2. 4 (2 0. 3) 20 .8 –2 3. 9 (2 2. 3) C he ek d ep th 31 .6 40 .2 23 .2 –2 8. 5 (2 5. 7) 22 .5 –2 8. 8 (2 6. 0) 22 .6 –3 1. 9 (2 7. 4) 21 .4 27 .3 –3 0. 6 (2 9. 0) 29 .2 –3 7. 0 (3 3. 1) 25 .5 –2 9. 5 (2 7. 7) E ye d ia m et er 27 .0 22 .5 23 .7 –2 9. 9 (2 5. 6) 21 .6 –3 0. 5 (2 5. 8) 24 .9 –3 0. 4 (2 7. 2) 32 .2 21 .6 –2 7. 6 (2 4. 4) 22 .7 –2 5. 4 (2 3. 9) 19 .5 –2 4. 6 (2 1. 8) Sn ou t w id th 30 .8 32 .2 27 .7 –3 4. 5 (3 1. 5) 27 .9 –3 4. 8 (3 2. 3) 30 .2 –4 0. 8 (3 4. 9) 29 .2 31 .8 –3 7. 2 (3 4. 2) 32 .9 –3 6. 0 (3 4. 2) 28 .4 –3 1. 8 (3 0. 0) In te ro rb ita l w id th 22 .9 23 .4 26 .9 –3 2. 8 (2 9. 3) 23 .3 –3 0. 6 (2 5. 8) 25 .0 –3 3. 6 (2 9. 8) 22 .1 23 .2 –2 6. 0 (2 4. 9) 23 .2 –2 8. 2 (2 5. 8) 20 .4 –2 3. 6 (2 1. 6) L ow er ja w le ng th 37 .7 38 .8 31 .2 –3 7. 3 (3 4. 4) 28 .9 –3 5. 0 (3 2. 7) 29 .6 –3 9. 1 (3 6. 1) 32 .9 37 .6 –4 0. 6 (3 9. 0) 37 .8 –3 9. 2 (3 8. 4) 33 .6 –3 8. 4 (3 6. 2) DIERICKX K. & SNOEKS J., A new paedophagous cichlid 13 Ta bl e 5. M er is tic s fo r P ro to m el as k ra m pu s sp . no v. ( ho lo ty pe a nd p ar at yp e) , co m pa re d w ith t he r an ge s of t he e xa m in ed s pe ci m en s of P . in si gn is (T re w av as , 19 35 ), H em ita en io ch ro m is s p. ‘ in si gn is l ik e’ , P. s pi lo pt er us ( Tr ew av as , 19 35 ), H em ita en io ch ro m is b ra ch yr hy nc hu s O liv er , 20 12 , H . u ro ta en ia (R eg an , 1 92 2) , C ap ri ch ro m is li em i ( M cK ay e & M ac ke nz ie , 1 98 2) a nd C . o rt ho gn at hu s (T re w av as , 1 93 5) . P. k ra m pu s sp . n ov . P. in si gn is H . s p. ‘i ns ig ni s lik e’ P. s pi lo pt er us H . b ra ch yr hy nc hu s H . u ro ta en ia C . o rt ho gn at hu s C . l ie m i H ol ot yp e P ar at yp e M er is tic s (n = 4 ) (n = 11 ) (n = 11 ) (n = 1 ) (n = 5 ) (n = 4 ) (n = 5 ) L on gi tu di na l s er ie s 32 31 31 –3 4 30 –3 4 29 –3 1 33 30 –3 4 31 –3 3 32 –3 3 U pp er la te ra l l in e 23 20 23 –2 6 21 –2 7 19 –2 6 22 21 –2 4 21 –2 5 25 –2 7 L ow er la te ra l l in e 14 17 13 –1 7 13 –1 6 12 –1 5 14 13 –1 7 13 –1 5 13 –1 6 U pp er g ill ra ke rs 5 5 4– 5 3– 4 3– 4 4 2– 4 3– 4 3– 5 L ow er g ill ra ke rs 11 10 9– 13 11 –1 2 9– 12 10 9– 11 9– 12 11 –1 2 D or sa l fi n sp in es 17 17 16 –1 8 16 –1 8 15 –1 6 17 16 –1 7 15 –1 7 17 D or sa l fi n ra ys 11 12 10 –1 1 9– 10 10 –1 1 10 9– 10 10 10 –1 1 A na l fi n ra ys 9 10 9– 10 8– 9 8– 10 9 9 9 9– 10 Pe ct or al fi n ra ys 15 13 14 –1 5 13 –1 5 12 –1 5 14 14 –1 5 13 –1 4 11 –1 4 U pp er o ra l j aw te et h 37 40 43 –5 0 24 –4 6 21 –3 8 37 35 –4 8 33 –4 2 44 –4 7 L ow er o ra l j aw te et h 31 36 34 –4 2 24 –3 4 23 –3 6 32 25 –3 7 42 –5 0 44 –5 9 In ne r t ee th ro w s 1 1 2 1– 2 1– 2 1 1– 2 1– 3 1– 2 V er te br ae 31 32 31 29 –3 1 29 30 30 30 –3 1 31 European Journal of Taxonomy 672: 1–18 (2020) 14 isognathous. Lower jaw long. Posterior side of lower jaw protrudes anteriorly. Anterior side of lower jaw slightly wider than posterior side. Deep chin. Larger specimen with larger mouth inclination and deeper chin. Lip longer than half length of lower jaw. Lips normal. Lower lip with mucosa embedding teeth. Preopercle also inclined. Long and slender gill rakers. TeeTH. Outer row of teeth on upper and lower jaws mostly unequally bicuspid and some posterior teeth unicuspid in smaller specimen; anterior teeth exclusively unicuspid on both jaws of larger specimen. Teeth straight and not curved inwards. Anterior cusps of teeth on outer row in both jaws larger than posterior cusps in smaller specimen. Anterior teeth larger than posterior teeth in smaller specimen. One inner row of irregularly placed tricuspid teeth on both jaws in smaller specimen. Posterior and inner teeth in larger specimen not readily observable, being to a large extent or fully covered by fleshy gums. Teeth closely set (space between teeth about half to one tooth width). Fins. Pectoral fin origin behind level of dorsal fin origin in smaller specimen. Position of pectoral fin origin unknown in larger specimen because of damage. Pelvic fin origin positioned slightly more backwards than level of dorsal fin origin. Pectoral fin of holotype and pelvic fin in both types almost to level of anus. Anal fin anterior to level of first soft dorsal fin ray. Small scales on base of caudal fin rays. Fig. 5. Photograph of preserved paratype (RMCA 99-041-P-4767) of Protomelas krampus sp. nov., shortly after preservation. Fig. 6. Photograph of live specimen of Protomelas krampus sp. nov. (specimen not preserved; length unknown) (copyright Ad Konings). DIERICKX K. & SNOEKS J., A new paedophagous cichlid 15 Colour pattern in life Based on a photograph by Konings (2016) (Fig. 6). Body generally greyish. Head and pectoral fin base yellowish. Pelvic fin with white distal part of leading edge. Five orange-brownish eggspots on anal fin. Continuous dark midlateral band from about one eye length behind opercle to caudal fin. Supralateral row of darks spots. Dark spots also present just below dorsal fin. Some spots are arranged in an interrupted vertical bar pattern. Fig. 7. Distribution map of Protomelas krampus sp. nov. Red star = holotype; red dot = paratype; green triangles = possible sightings by Konings (2016); orange square = possible sighting by McKaye & Kocher (1983); yellow diamond = possible sighting by Stauffer (pers. comm.). Inset: map of Africa with indication of area of Lake Malawi. European Journal of Taxonomy 672: 1–18 (2020) 16 Colour pattern in preserved specimens Based on photographs by McKaye & Kocher (1983) and Snoeks (2004) (Fig. 5). Body generally brown or greyish. Dorsum somewhat darker than belly. Darker on dorsal parts of head and body contiguous with dorsal fin base. Clear dark maculae on spiny part of dorsal fin, possibly also on soft dorsal fin part and caudal fin. Continuous dark midlateral band from one eye length or about three scales behind opercle to caudal fin. One supralateral and one subdorsal row of darks spots. Some spots as subtle, incomplete vertical bars. Both types currently pale-coloured, probably due to light exposure (Fig. 4). Geographical distribution (Fig. 7) The specimens of P. krampus sp. nov. were found in Lukoma Bay (11°22.50′ S, 34°52.00′ E), south of Mbamba Bay, Lake Malawi (Tanzania) and at rocks just south of Mara Point (12°11.34′ S, 34°41.73′ E), Aldeia Mala, Lake Malawi (Mozambique), at depths of 32.5–33.2 m. Three others specimens that also may belong to this species were caught near Otter Point (14°03′ S, 34°49′ E), Mangochi, Lake Malawi (Malawi), at a depth of 7–20 m (McKaye & Kocher 1983). It has also been observed near Chizumulu and Likoma Islands (Konings 2016) and Mazinzi Reef (Stauffer, pers. comm.). Hence the species has a confirmed distribution in the central-eastern part of the lake, but it may also occur in the southern part. Ecology The behaviour and ecology of specimens most likely belonging to this species have been observed by McKaye & Kocher (1983) and Konings (1989, 2016). They observed this species feeding on eggs and fry while stealing them from mouth-brooding females of other cichlid species. The paedophage rams these females from above on the snout and the brooding females may release some eggs or larvae upon this impact. The brood can then be snatched by P. krampus sp. nov. The inclined position of the mouth enables the fish to immediately grab the brood since it is already in a good position relative to the prey after ramming from above (Konings 1989, 2016). Discussion Based on its melanin pattern, the new species was assigned to the genus Protomelas. Eccles & Trewavas (1989) conducted an extensive review of the characteristics of all species of Protomelas. Based on these descriptions, only those species that are similar to the new paedophage species, P. krampus sp. nov., were included in the morphometric part of this study. Since P. krampus sp. nov. has only one inner tooth row, all twelve species with two or more inner rows (see diagnosis) were excluded from the detailed morphometric analyses. Eclectochromis ornatus (Regan, 1922), which according to Oliver (2012) and Konings (2016) belongs to Protomelas, was also excluded based on the number of inner tooth rows and melanin pattern as described by Eccles & Trewavas (1989). Only P. spilopterus, which was suggested by Eccles & Trewavas (1989) to be the undescribed paedophage species observed by McKaye & Kocher (1983), and P. insignis were retained for the morphometric comparison, as well as an undescribed species from this genus mentioned by Snoeks & Hanssens (2004) with some similar traits, H. sp. ‘insignis like’. In the morphometric analyses it was found that P. krampus sp. nov. is distinguished from its congeners among others by its large gape inclination, very short premaxillary pedicel, deep cheek, long lower jaw, deep chin, short and slender head, small interorbital width, and shorter predorsal and prepectoral distance. Both C. orthognathus and P. krampus sp. nov. have been observed showing a similar ramming behaviour (McKaye & Kocher 1983; Konings 2016), though the number of observations is limited; therefore, their strikingly similar morphology is probably linked to their food acquisition. The shorter head, the deep chin and short premaxillary pedicel of P. krampus sp. nov. enhance the aspect of an enlarged ventral part of the head. This may be an adaptation to the ramming behaviour typical of this species. Caprichromis orthognathus rams from beneath, whereas P. krampus sp. nov. rams from above with the ventral part DIERICKX K. & SNOEKS J., A new paedophagous cichlid 17 of the head. When the chin is enlarged, it is easier to use it as a ram from this orientation and possibly to have more impact on the snout of the prey. This may also explain the large gape inclination. The different angle of attack and slight differences in morphology may be explained by niche partitioning (McKaye & Kocher 1983). The precise phylogenetic relationships between the paedophagous species should, however, be further studied with genetic analyses and a thorough taxonomic revision. During our analyses, it became clear that there may be an additional undescribed species within the genus Protomelas. The lectotype of P. spilopterus and one paralectotype (tag 2583 within BMNH 1935.6.14.652-657) differ from the other paralectotypes in several features. The head of these two specimens is steeper and the neurocranial crest appears to be more rounded. They show a clear chin, whereas the other paralectotypes lack a chin. The jaws of the lectotype and some paralectotypes are rounded, while the others have wide and anteriorly flattened jaws. The lacrimal appears to be somewhat larger and has a more rounded anterior side in the lectotype and paralectotype compared to the other paralectotypes. The caudal fin of the lectotype and paralectotype is emarginate, whereas the other paralectotypes of P. spilopterus have a truncate caudal fin with a longer dorsal lobe than ventral lobe. Furthermore, the lectotype has bicuspid teeth, the second cusp of which is very small, in the outer row on both jaws, and a mixture of uni- and tricuspid teeth on the two inner rows. Its teeth are curved inwards. The teeth of all paralectotypes are angled forwards and are uniquely unicuspid and conical, and there is only one inner tooth row on both jaws. The deepest point of the body occurs at the level of the pectoral fin origin in the lectotype and posterior to the pectoral fin origin in most paralectotypes. The eggspots on the anal fin of the lectotype are placed in three rows: the distal row with seven spots, the middle row with three spots and one spot in the proximal row. Only one other paralectotype has eggspots in two rows with five spots on the distal row and four or five spots on the proximal row. A more detailed study is necessary to assess whether or not the type series is polyspecific. Acknowledgements We acknowledge the project members of the SADC/GEF Taxonomy team and the crew of the R/V Usipa for their logistical support. We are grateful to Oliver Crimmen and James MacClaine (Natural History Museum, London) for the loan of some specimens under their care and to Ad Konings for the use of his photograph of a live specimen. References Eccles D.H. & Trewavas E. 1989. Malawian Cichlid Fishes: the Classification of some Haplochromine Genera. Lake Fish Movies, Herten, West Germany. Fricke R., Eschmeyer W.N. & Van der Laan R. (eds) 2020. 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Hydrobiologia 748: 39–60. https://doi.org/10.1007/s10750-013-1692-5 Manuscript received: 1 February 2020 Manuscript accepted: 11 May 2020 Published on: 23 June 2020 Topic editor: Rudy Jocqué Section editor: Felipe Polivanov Ottoni Desk editor: Danny Eibye-Jacobsen Printed versions of all papers are also deposited in the libraries of the institutes that are members of the EJT consortium: Muséum national d’histoire naturelle, Paris, France; Meise Botanic Garden, Belgium; Royal Museum for Central Africa, Tervuren, Belgium; Royal Belgian Institute of Natural Sciences, Brussels, Belgium; Natural History Museum of Denmark, Copenhagen, Denmark; Naturalis Biodiversity Center, Leiden, the Netherlands; Museo Nacional de Ciencias Naturales-CSIC, Madrid, Spain; Real Jardín Botánico de Madrid CSIC, Spain; Zoological Research Museum Alexander Koenig, Bonn, Germany; National Museum, Prague, Czech Republic. https://doi.org/10.11646/zootaxa.3410.1.3 https://doi.org/10.1016/S0065-2504(00)31005-4 https://doi.org/10.1007/s10750-013-1692-5