A taxonomic approach on diagnostic characters used to define new pterosaur taxa and an estimation of pterosaur diversity

FERNANDES, DENIS LUIZ; NUNES, IVAN; COSTA, FABIANA R.

doi:10.1590/0001-3765202120201568

Abstract

Diagnostic characters from 227 pterosaur species were listed, separated into cranial or post-cranial elements and counted. From 21 post-cranial and 23 cranial elements, most diagnostic characters were related to phalanges (15%) and rostrum. Post-cranial characters comprise 44.23%, and cranial characters 55.77% of all characters used in pterosaur diagnoses. The highest correlation between diagnostic features occurs between the coracoid and the scapula. 25.11% and 28.63% of sampled taxa were diagnosed with 3-4 and 5-6 characters, respectively. The mean number of 6.79 characters was found in specimens with both cranial and post-cranial elements, and 4.86 and 4.17 in those with just cranial or post-cranial elements, respectively. 31 from 227 species (13.7%) were erected based on single elements, which are most frequently complete or partial mandibles (n=18). We estimate that 23.4% of the total pterosaur genera are currently known, with 90% of this diversity to be unveiled up to 2145. As the requirements of broad and cautious revision of genus/group must be undertaken, and some deposits will provide mostly fragmented and incomplete material, the assignment of fairly incomplete specimens to the most inclusive taxonomic level is feasible. Tracing this scenario can guide future works on the description of new pterosaur taxa.

Key words
Morphology-based species; Pterosauria; Systematic Biology; Taxonomy

INTRODUCTION

Delineating species and their taxonomy has been traditionally a matter of recognizing morphological characters (Schwentner et al. 2011SCHWENTNER M, TIMMS BV & RICHTER S. 2011. An integrative approach to species delineation incorporating different species concepts: a case study of Limnadopsis (Branchiopoda: Spinicaudata). Biol J Linn Soc 104: 575-599.) as structural attributes of organisms that are primarily recognized as different from any other. For centuries, Morphology has been the primary or sole source of data for delimiting species (Cook et al. 2010COOK LG, EDWARDS RD, CRISP MD & HARDY NB. 2010. Need morphology always be required for new species descriptions? Invertebr Syst 24: 322-326.). Under the requirement of a species being unique and identifiable following a specific code, each name has to be linked to a type specimen, and this identification is associated to a species concept (Cook et al. 2010COOK LG, EDWARDS RD, CRISP MD & HARDY NB. 2010. Need morphology always be required for new species descriptions? Invertebr Syst 24: 322-326.). That of Mayr’s (1996) defining species as “a morphological kind that is different from other such kinds” particularly restricts data to morphological characters (Cook et al. 2010COOK LG, EDWARDS RD, CRISP MD & HARDY NB. 2010. Need morphology always be required for new species descriptions? Invertebr Syst 24: 322-326.). Despite data defining morphology-based species have been currently complemented by other data source such as DNA sequence data, which has fomented plenty of debate on the sufficiency of morphological data alone to define species (e.g., Ebach & Carvalho 2005a, b, Packer et al. 2009PACKER L, GIBBS J, SHEFFIELD C & HANNER R. 2009. DNA barcoding and the mediocrity of morphology. Mol Ecol Resour 9: 42-50.), this cannot be applied to some areas that usually can count solely on structure (Morphology), such as the case of Paleontology. Indeed, recognition of paleontological species relies almost exclusively on their morphological differences, which is hampered by the often fragmentary and isolated nature of fossils (Forey et al. 2004FOREY PL, FORTEY RA, KENRICK P & SMITH AB. 2004. Taxonomy and fossils: a critical appraisal. Phil Trans R Soc Lond B 359: 639-653.). This explains the differences between the nature of elements that are used to define new taxa, ranging from cranial to post-cranial elements or both, and from complete to fairly incomplete material.

When it comes to pterosaurs the number of characters raised as diagnostic to define a new species varies from one (e.g., Azhdarcho lancicollis Nessov, 1984, Bennettazhia oregonensis (Gilmore, 1928), Domeykodactylus ceciliae Martill, Frey, Diaz & Bell, 2000, Gnathosaurus subulatus Meyer, 1833, “Huaxiapterus” corollatus Lü, Jin, Unwin, Zhao, Azuma & Ji, 2006, Nyctosaurus lamegoi Price, 1953, Rhamphorhynchus etchesi O’Sullivan & Martill, 2015 and Tupuxuara longicristatus Kellner & Campos, 1988) to up to 29 features (Eudimorphodon ranzii Zambelli, 1973), which could be related to the completeness degree of material (the more complete the specimen, the higher number of osteological features to be eventually pointed as diagnostic). When it comes to the type of characters (i.e., autapomorphic or synapomorphic), there is also a noticeable variation in this number of diagnostic features that could be assigned to methodological bias whether in complete specimens or not. For instance, Mythunga camara Molnar & Thulborn, 2007 is an Early Cretaceous pterodactyloid pterosaur described based on 10 original features of an incomplete snout and mandible, but only two of them were identified as autapomorphic. On the other hand, the abovementioned and much more complete Chinese tapejarid “Huaxiapterus” corollatus, a partial skeleton and skull, is defined by a single supposed autapomorphy (a distinctive hatched-shaped process on the cranial crest). There are also taxa (e.g., species of the genus Anhanguera Campos & Kellner, 1985, Pinheiro & Rodrigues 2017PINHEIRO FL & RODRIGUES T. 2017. Anhanguera taxonomy revisited: is our understanding of Santana Group pterosaur diversity biased by poor biological and stratigraphic control? PeerJ 5: e3285.) largely diagnosed by subtle differences in cranial anatomy based particularly on the morphology and position of structures as crests, which may presumably be sexual dimorphisms or ontogenetic variations (Bennett 1992BENNETT SC. 1992. Sexual dimorphism of Pteranodon and other pterosaurs, with comments on Bennett SC. 2000. “Inferring stratigraphic position of fossil vertebrates from the Niobrara Chalk of western Kansas.” Kansas Geol Survey Bull 244(1): 26., Manzig et al. 2014MANZIG PM, KELLNER AWA, WEINSCHUTZ LC, FRAGOSO CE, VEGA CS, GUIMARÃES GB, GODOY LC, LICCARDO A, RICETTI JHZ & MOURA CC. 2014. Discovery of a Rare Pterosaur Bone Bed in a Cretaceous Desert with Insights on Ontogeny and Behavior of Flying Reptiles. PLoS ONE 9(8): e100005.). However, neither dimorphic or ontogenetic aspects, nor the type of characters termed as diagnostic are here considered, and such discussion is beyond the scope of this paper.

The systematic biology, as it is known, is based on the description of an organism that supports taxonomic recognition, and the diagnosis of new or revised taxa has long been considered part of systematic accounts (Cifelli & Kielan-Jaworowska 2005CIFELLI RL & KIELAN-JAWOROWSKA Z. 2005. Diagnosis: Differing interpretations of the ICZN. Acta Palaeontol Polon 50: 650-652.). The International Code of Zoological Nomenclature (ICZN) provides definitions and a set of rules on how to name newly described organisms, assuring the stability of the zoological nomenclature. However, it does not set a norm on the amount (from 1-29 features in pterosaurs) or nature of the diagnostic characters used to define new taxa, which is widely variable among researchers and depends on the nature of studied organisms. The character-based species, as defined by Nixon & Wheeler (1990)NIXON KC & WHEELER QD. 1990. An amplification of the phylogenetic species concept. Cladistics 6(3): 211-223. as “the smallest aggregation of populations (sexual) or lineages (asexual) diagnosable by a unique combination of character states in comparable individuals (semaphoronts)”, has the number of diagnostic traits to be considered to define a species as one of its major practical difficulties (Willmann & Meier 2000WILLMANN R. & MEIER R. 2000. A critique from the Hennigian species concept perspective. In: Wheeler QD & Meier R (Eds), Species concepts and phylogenetic theory: a debate. Columbia University Press, New York, p.101-118.). Thus, as a matter of debate and also to try to delineate a pattern regarding the most used structures for diagnosing pterosaur species, we have delineated three main aims to this study: to determine (1) the nature of elements from which the osteological characters that diagnose new species are defined, (2) the average number of characters used to diagnose pterosaur species, and (3) to make a projection concerning the rate of future pterosaur discoveries to predict these discoveries as to guide future works on the description of new pterosaur species.

Institutional abbreviations

IVPP - Institute of Vertebrate Paleontology and Paleoanthropology, Beijing, China; MN - Museu Nacional, Rio de Janeiro, Brazil; NHMUK - The Natural History Museum, London, UK; PIMUZ - Paläontologisches Institut und Museum, Universität Zürich, Switzerland; UJA - University of Jordan, Amman, Jordan.

MATERIALS AND METHODS

Data on diagnostic characters from all taxonomically diagnosable pterosaur species ever described up to August 2020 (n = 227) were compiled from The Paleobiology Database (PaleoDB: www.paleobiodb.org) and published literature. Diagnostic characters are here interpreted as differential character states (i.e., uniquely shared by all members of a taxon but not by non-members) or a unique and differential combination of characters used to define a taxon. The former is here termed as autapomorphic (as a unique apomorphy to a taxon or a group of organisms), as discriminated by Dubois (2017)DUBOIS A. 2017. Diagnoses in zoological taxonomy and nomenclature. Bionomina 12: 63-85.. Here we refrain from differing the type of characters in the sense of separating autapomorphic from synapomorphic ones (i.e., whether unique from a single taxon or shared with other taxa). All of them are termed as diagnostic and considered according to their nature (cranial or post-cranial).

The final dataset comprises (for each listed species) nature of preserved skeletal material (cranial, post-cranial or both), the number of characters used to diagnose each pterosaur species, completeness degree (i.e., complete or partial skeletons, and which parts are preserved in incomplete material), year of description, period, locality and country (see the supplementary DataSet by Fernandes et al. 2021 at doi:10.17632/w7thrrs9dh.1).

As to provide the most updated compilation of diagnosable pterosaur species so far, we have checked along for synonyms and nomina dubia (not considered). Despite the fact that other pterosaur species compilations have been provided previously (e.g., Andres 2010ANDRES BB. 2010. Systematics of the Pterosauria. PhD Dissertation, Yale University, 366 p., Butler et al. 2013BUTLER RJ, BENSON RB & BARRETT PM. 2013. Pterosaur diversity: untangling the influence of sampling biases, Lagerstätten, and genuine biodiversity signals. Palaeogeogr Palaeoclimatol Palaeoecol 372: 78-87., Dean et al. 2016DEAN CD, MANNION PD & BUTLER RJ. 2016. Preservational bias controls the fossil record of pterosaurs. Palaeontology 59: 225-247.), our purpose differs by focusing on the number and nature of characters used in the original diagnoses of pterosaur species, as well as predicting the rate of future pterosaur discoveries. It is worth mentioning that once we have considered the elements that have historically been used as original diagnostic features, we disregarded whether the characters are currently valid or not. Neither aspects of pterosaur diversity nor the quality of fossil record has been evaluated or discussed herein.

Once fossil species are mainly diagnosed on the basis of osteological characters, cranial and post-cranial elements used to define these characters in each species were determined. These elements were then individually counted regarding the number of times they were used when diagnosing species that comprised only cranial and both cranial and post-cranial material (cranial elements), and only post-cranial and both cranial and post-cranial material (post-cranial elements). Osteological elements were only considered once per diagnosis (e.g., if a taxon was diagnosed using two distinct phalangeal features, it was counted as “phalangeal elements” - 1). Moreover, when these elements were combined with others to term a single diagnostic character, they were counted separately (e.g., if a taxon was diagnosed by the hypothetical diagnostic character “wing metacarpal shorter than ulna and first wing phalanx, with a pronounced posterior curvature”, it was counted as “phalangeal elements” - 1, “metacarpal elements”- 1, and “ulnar elements” - 1). Subsequently the frequency (%) of these (cranial and post-cranial) elements related to diagnostic characters was determined in order to indicate which elements would have been most used in the diagnosis of new species.

Mean, median and mode were calculated from the number of characters used to diagnose each pterosaur species. The frequency (%) of the amount of characters (ranging from the min-max values of 2 - 31) that diagnosed new pterosaur species was calculated, as well as the frequency of each cranial and post-cranial element used to diagnose these species.

A Principal Component Analysis (PCA) was applied to analyze similarity patterns of characters frequency between diagnoses due to the very large dataset (Jollife & Cadima 2016). PCA is an orthogonal linear transformation of the data for a new coordinate system, reducing the dimensionality of such datasets, increasing interpretability and minimizing information loss (Jolliffe 2002JOLLIFFE IT. 2002. Principal Component Analysis, Series: Springer Series in Statistics, 2nd ed., New York: Springer, 487 p.). In this analysis, the greatest variance for any projection of data is along the first coordinate (Principal Component 1 - PC1) and the second greatest variance is along the second coordinate (Principal Component 2 - PC2), and so on, being the number of principal components less than or equal to the number of original variables (Jolliffe 2002JOLLIFFE IT. 2002. Principal Component Analysis, Series: Springer Series in Statistics, 2nd ed., New York: Springer, 487 p.). The Hierarchical Cluster Analysis was performed as a complement with the linkage criterion of UPGMA (unweighted pair group method with arithmetic mean) and applying a correlation similarity index to find out which any given pair of characters join together in the tree diagram (Sokal 1958SOKAL M 1958. A statistical method for evaluating systematic relationships. Univ Kans sci bull 38: 1409-1438., Krebs 1999KREBS CJ. 1999. Ecological Methodology. Menlo Park, Addison Wesley Educational Publishers, 620 p., Nielsen 2016NIELSEN F. 2016. Hierarchical Clustering. In: Introduction to HPC with MPI for data science. Springer International Publishing.). The goal is to build a tree diagram where the characters that were more used in the same diagnosis are placed on branches that are close together.

To estimate pterosaur diversity and to make a projection concerning the rate of future pterosaur discoveries, the number of specimens assigned to each genus was taken from the PaleoDB (Alroy 2013ALROY J. 2013. North American Fossil Mammal Systematics. Paleobiology Database. Available online at: http://paleobiodb.org/cgibin/bridge.pl?page=OSA_3_North_American_mammals.
http://paleobiodb.org/cgibin/bridge.pl?p... ) downloaded on August 16^th, 2019. From this date up to August 2020 new genera were sourced from the literature. Here we applied the Abundance-based Coverage Estimator (ACE) (Chao & Lee 1992CHAO A & LEE SM. 1992. Estimating the number of classes via sample coverage. J Am Sta Assoc 87: 210-217., Chao & Yang 1993CHAO A & YANG MC. 1993. Stopping rules and estimation for recapture debugging with unequal failure rates. Biometrika 80: 193-201.) as a statistical method to consider the incompleteness of the fossil record (following Wang & Dodson 2006WANG SC & DODSON P. 2006. Estimating the diversity of dinosaurs. Proc Natl Acad Sci USA 103(37): 13601-13605.). The ACE model estimates the number of discoverable genera also comprising future discoveries, and only takes into account genera considered scarce (i.e., those with ten or less individuals assigned to a genus), which avoid inaccuracies (e.g., those motivated by difficulties in estimating the exact number of material available for abundant genera, such as Pteranodon, with more than a thousand individuals known so far (Bennett 2000BENNETT SC 2000. Inferring stratigraphic position of fossil vertebrates from the Niobrara Chalk of western Kansas. Curr Res Earth Sci, Kansas Geological Survey Bulletin, 244(Part 1), 26 p.)). The diversity was estimated with the following equation:

Estimated Diversity = D_{abun} + \frac{D_{rare}}{C_{rare}} + \frac{f_{1}}{C_{rare}} γ_{rare}^{2}

Where

γ_{rare}^{2} = \max [\max (\frac{D_{rare} \sum i (i - 1) f_{i}}{C_{rare} (\sum i f_{i})^{2}} - 1, 0) (1 + \frac{1 - C_{rare} \sum i (i - 1) f_{i}}{C_{rare} \sum i f_{i} - 1}), 0]

and

C_{rare} = 1 - \frac{f_{1}}{n_{rare}}

D_abun is the number of abundant genera (n>10), D_rare is the number of rare genera (n<10), n_rare is the number of individuals among rare genera, and f_i is the number of individuals known from exactly i individuals. All calculations were made using the LibreOffice® Calc software and Past4.3 was used to generate the dendrogram.

It is worth mentioning that specimens not assigned to a specific genus (e.g., IVPP V 17959, a wukongopterid; Cheng et al. 2016CHENG X, JIANG SX, WANG XL & KELLNER AWA. 2016. New information on the Wukongopteridae (Pterosauria) revealed by a new specimen from the Jurassic of China. PeerJ 4: e2177.) were not considered in the estimation using the ACE model, neither ichnotaxa nor species without a valid diagnosis. Here we have accounted for the “discoverable” and “assignable” pterosaur genera with current technology and taxonomic methods, and thus provided a lower estimate of the ever existed diversity (Wang & Dodson 2006WANG SC & DODSON P. 2006. Estimating the diversity of dinosaurs. Proc Natl Acad Sci USA 103(37): 13601-13605.) since the original diversity cannot be recovered.

Other data related to each species, such as year of the species’ description and the number of assigned specimens to a species, were also used to predict future pterosaur discoveries and to produce statistics for estimating pterosaur diversity, respectively. The prediction of future discoveries was performed by fitting a logistic accumulation curve of the form y=807/(1+806*e^(-0, 0.026026*t)) to the cumulative counts of known genera throughout the years using the estimation of pterosaur diversity as the point where the curve becomes an asymptote.

RESULTS AND DISCUSSION

Which osteological elements are the most employed to diagnose new pterosaur species?

From 21 post-cranial elements, most diagnostic characters were related to phalanges (15%), followed by humeri (13%) and vertebrae (12.25%) (Figure 1), and from 23 cranial elements the most used cranial-related characters regard those of the rostrum, as follows: teeth (16.20%), mandible (12.93%) and premaxilla (10.44%) (Figure 2). Post-cranial characters comprise 44.49%, and cranial characters 55.51% of all characters used in pterosaur diagnoses. If species with both cranial and post-cranial elements are considered, teeth (9.99%) account for the majority of characters, followed by mandible (7.64%), phalanges (6.61%) and humeri (5.43%) (Figure 3).

Figure 1
Frequency of post-cranial elements diagnosing new pterosaur taxa.

Figure 2
Frequency of cranial elements diagnosing new pterosaur taxa.

Figure 3
Frequency of cranial and post-cranial elements diagnosing new pterosaur taxa.

In PCA analysis, it was found that the first two components (PC1 and PC2) correspond to 32.28% of all variance. and the other two (PC3 and PC4) to 6.50% and 5.34%, respectively. The scatterplot of PC1-PC4 scores are shown in Figure 4 but, as explained before, the representation of the variance is low in PC3 and PC4. Thus, we have limited our approach to the first two components. The reduced space of the first two components (Figure 5) show that PC1 has a positive correlation especially with the frequency of cranial elements, while PC2 mostly has positive correlation with the frequency of post-cranial elements. The scatter plot groups in the negative side of both axes the features that have low frequency in diagnosis and that are mostly used to diagnose the most complete specimens with both cranial and post-cranial elements. Factor loadings are presented in Figure 6. When considering the axes alone, it can be seen that taxa diagnosed with only cranial elements are influencing PC1, with Austriadactylus cristatus Dalla Vecchia, Wild, Hopf & Reitner, 2002, Istiodactylus sinensis Andres & Qiang, 2006, Maaradactylus spielbergi Veldmeijer, 2003, Haopterus gracilis Wang & Lü, 2001, and Cearadactylus atrox Leonardi & Borgomanero, 1985, respectively, with major descendant contribution. PC2 is being influenced by taxa with only post-cranial elements, with Ningchengopterus liuae Lü, 2009, Changchengopterus pani Lü, 2009, Vesperopterylus lamadongensis Lü, Meng, Wang, Liu, Shen & Zhang, 2017, Orientognathus chaoyngensis Lü, Pu, Xu, Wei, Chang & Kundrát, 2015, and Carniadactylus rosenfeldi Dalla Vecchia, 1995, respectively, with major descendant contribution. Taxa diagnosed with both cranial and post-cranial elements influence both axes, depending on how many characters used in the diagnosis are cranial or post-cranial (Figure 6).

Figure 4
The six possible PCA scatter plot combinations for PC1 to PC4 of post-cranial (circle) and cranial (triangle) osteological features.

Figure 5
PCA scatter plot (PC1 and PC2) of the diagnostic signal of post-cranial (circle) and cranial (triangle) osteological features.

Figure 6
PCA factor loadings (PC1 and PC2) of taxa described with only post-cranial (circle), cranial (triangle) and both cranial and post-cranial (cross) osteological features.

The Hierarchical Cluster Analysis shows a dendrogram in which osteological elements are frequently used together to erect new taxa, which is organized in eight main clusters (Figure 7). Most clusters group features that are often found together due to being anatomically near to each other, but it is not always the case because of the low frequency of some of the features (e.g., a cluster grouping the ischium with the occipital bone). The highest correlation between diagnostic features occurs between the coracoid and the scapula. Other features often used together for diagnostic purposes include both nasoantorbital and orbital fenestrae; fibula and tarsus; and femur and tibia. Features that do not often occur with other specific features are pteroid, lacrimal, and dentary.

Figure 7
Dendrogram showing the co-occurrence of diagnostic features.

How many characters on average are used to diagnose pterosaur taxa?

Mode and median were 5.0, with mean of 5.6. There was also a strong negative correlation between the number of diagnostic features and the percentage of taxa (-0.77), which means that less taxa are diagnosed with more characters. 25.11% and 28.63% of pterosaur taxa were diagnosed with 3-4 and 5-6 characters (Figure 8). Despite this pattern, some taxa are outstandingly out of the normal curve as quite complete specimens being diagnosed within the range of 13-29 characters (e.g., Eudimorphodon ranzii and Vesperopterylus lamadongensis Lu, Meng, Wang, Liu, Shen & Zhang, 2017, with 31 and 15 cranial and post-cranial diagnostic characters, respectively).

Figure 8
Frequency of characters used to diagnosis new pterosaur taxa.

There is a quite obvious tendency of having more diagnostic characters in more complete specimens, which is numerically substantiated by a mean of 6.79 characters in specimens with both cranial and post-cranial elements, and 4.86 and 4.17 in those with just cranial or post-cranial elements, respectively. Notwithstanding, there are fairly complete specimens with a sole diagnostic feature, such as the case of “Huaxiapterus” corollatus diagnosed by a hatchet-shaped process on the cranial crest, as well as “Huaxiapterus” atavismus Lü, Teng, Sun, Shen, Li, Gao & Liu, 2016 and “Huaxiapterus” benxiensis Lü, Gao, Xing, Li & Sun, 2007, with only two diagnostic elements (Lü et al. 2006LÜ JC, JIN XS, UNWIN DM, ZHAO LJ, AZUMA Y & JI Q. 2006. A new species of Huaxiapterus (Pterosauria: Pterodactyloidea）from the Lower Cretaceous of western Liaoning, China with comments on the systematics of tapejarid pterosaurs. Acta Geol Sin 80: 315-326., 2007, 2016). Caviramus shesaplanensis Frösbisch & Frösbisch, 2006 (PIMUZ A/III 1225), on the other hand, consists of an incomplete mandible and is diagnosed by 10 characters, such as the case of Cretornis hlavaci Fric, 1881 (an incomplete left wing) with 14 diagnostic features (Averianov & Ekrt 2015AVERIANOV A & EKRT B. 2015. Cretornis hlavaci Frič, 1881 from the Upper Cretaceous of Czech Republic (Pterosauria, Azhdarchoidea). Cretaceous Res 55: 164.).

What are the problems in taxonomy of fossil taxa anyway?

Theoretical and practical problems concerning the erection of higher taxa are currently being addressed and hamper the efficiency and transparency of the taxonomical work (Komarek & Beutel 2006KOMAREK A & BEUTEL RG. 2006. Problems in taxonomy and suggestions for a standardized description of new insect taxa. Entomol Prob 36(2): 55-70.). If taxonomy of extant taxa can benefit from molecular studies using conservative and fast evolving genes for phylogenetic reconstructions on both high and lower levels, respectively (Komarek & Beutel 2006KOMAREK A & BEUTEL RG. 2006. Problems in taxonomy and suggestions for a standardized description of new insect taxa. Entomol Prob 36(2): 55-70.), extinct taxa can basically count, as already mentioned, solely on morphology itself. This increases the concern about making (good) choices of suitable characters as a crucial stage of appropriate taxonomic work (Komarek & Beutel 2006KOMAREK A & BEUTEL RG. 2006. Problems in taxonomy and suggestions for a standardized description of new insect taxa. Entomol Prob 36(2): 55-70.). Thus, if we mainly deal with combination of morphological characters to advocate species recognition (not considering here the discussion on chronospecies and stratospecies, which is beyond the scope of this paper), our selection of characters relies on how deep is our taxonomic approach. This directs towards an easily detectable issue as we are dealing with species recognition based solely on morphological differences of specimens that are usually fragmentary and highly incomplete: the level of taxonomic identification depends on which parts of the morphology is preserved, and how complete they are. It is obviously different to describe individual parts as separate species or a fairly complete skeleton, and depending on the amount of parts we have (i.e., a single element, a bunch of cranial or/and post-cranial elements), we can turn to even fine details on the morphological investigation of perceptible differences (i.e., deepen the taxonomic level of investigation).

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Table I
Generic diversity (richness) estimated for each Mesozoic periods and the entire Mesozoic. Since some genera are found in the interface of two epochs, the sum of the richness of these subperiods do not add up to the richness of the entire Mesozoic.

However, how deep we go on this task is constantly a matter of debate, with some advocating against (and even strongly refusing to) the erection of new taxa based on single elements (specially fragmentary ones) as it could bring excessive noise to phylogenetic analysis (e.g., less resolved consensus trees and increased numbers of EMPTs; Huelsenbeck 1991HUELSENBECK JP. 1991. When are fossils better than extant taxa in phylogenetic analysis? Syst Zool 40: 458-469., Wiens and Reeder 1995, Wiens 2003WIENS JJ. 2003. Missing data, incomplete taxa, and phylogenetic accuracy. Syst Biol 52: 528-538.), or even create systematic problems to be further solved on late reassessments of these taxa when insufficient study of types or taxa have created synonyms. This can happen when the authors do not consider reviewing all species of a group under consideration, which creates an insufficient background to substantiate the introduction of a new species, tending to produce synonyms (Komarek & Beutel 2006KOMAREK A & BEUTEL RG. 2006. Problems in taxonomy and suggestions for a standardized description of new insect taxa. Entomol Prob 36(2): 55-70.). The lack of this critical approach to erect new taxa without sufficient comparison with other species and/or an extensive review may lead to inadequate taxonomic results. A recent example is the case of Thalassodromeus oberlii (Headden & Campos 2014HEADDEN JA & CAMPOS HBN. 2014. An unusual edentulous pterosaur from the Early Cretaceous Romualdo Formation of Brazil. Histor Biol 27: 815-826.), formerly “Banguela” oberlii described as a new species of dsungaripterid pterosaur based on an incomplete mandible from the Romualdo Formation (Santana Group, northeastern Brazil) (Pêgas et al. 2018PÊGAS RV, COSTA FR & KELLNER AWA. 2018. New information on the osteology and a taxonomic revision of the genus Thalassodromeus (Pterodactyloidea, Tapejaridae, Thalassodrominae). J Vert Paleontol 38(2): e1443273.). This synonymization has been proposed as none of the four autapomorphies erected for “Baguela” oberlii could distinguish it from Thalassodromeus sethi Kellner & Campos, 2002, and the recognition of a second species of Thalassodromeus Kellner & Campos, 2002 would in turn reflect the speciose nature of some pterosaur taxa from this formation (Pêgas et al. 2018PÊGAS RV, COSTA FR & KELLNER AWA. 2018. New information on the osteology and a taxonomic revision of the genus Thalassodromeus (Pterodactyloidea, Tapejaridae, Thalassodrominae). J Vert Paleontol 38(2): e1443273.). Nonetheless, if requirements of a broad revision of genus/group are properly undertaken, we can walk the path to assign these fairly incomplete specimens to the most inclusive taxonomic level.

Another abovementioned topic that can be debated is that the correct identification of fragmented fossils has proven to be difficult, and because of this reaching a more inclusive taxonomic level to erect a new species can raise doubts on the validity of this species. The severity of this issue is directly proportional to the degree of fragmentation displayed by specimens. A single piece of element demands a deepened analysis on its morphological features that can be potentially diagnostic. This varies depending on the nature of this element (e.g., a plain bone diaphysis or a piece of vertebra). The holotype of the monotypic species Araripedactylus dehmi Wellnhofer, 1977, for instance, consists of a single first phalanx embedded in a limestone concretion that was originally allocated into the Pterodactyloidea, and lately considered to belong to the Ornothocheiroidea (sensu Kellner) based on its provenance by Kellner & Tomida (2000)KELLNER AWA & TOMIDA Y. 2000. Description of a new species of Anhangueridae (Pterodactyloidea) with comments on the pterosaur fauna from the Santana Formation (Aptian-Albian), Northeastern Brazil. Nat Sci Mus Monogr 17: 1-135., who was not able to confirm none of its autapomorphies (even though seven were erected).

Indeed, few features can be taken from pterosaur phalanges themselves, particularly if their extremities are lacking/damaged (such as the case of A. dehmi). Notwithstanding, the case of other elements such as mandible is fairly different, but it depends on the completeness level of the specimen that is being described. If we take as an example the ventral shape (concave) of the mandibular symphysis that diagnoses the only element of the dsungaripteroid Tendaguripterus recki Unwin & Heinrich, 1999, which is the best known taxon from the Upper Jurassic Tendaguru Beds of Tanzania (Kellner et al. 2007KELLNER AWA, MARTINS AMS & FORD TL. 2007. A survey of pterosaurs from Africa with the description of a new specimen from Morocco. In: Carvalho IS et al. (Eds), Paleontologia. Cenários de Vida 1, p. 257-267.), a mapping on the diagnostic characters of all the analyzed species in this study shows that the shape of dorsal/ventral margins of the mandibular symphysis can be found also diagnosing Argentinadraco barrealensis Kellner & Calvo, 2017 (mandibular symphysis with marked concave ventral margin in lateral view), Aussiedraco molnari Kellner, Rodrigues & Costa, 2011 (dorsal margin of mandibular symphysis markedly convex, ventral margin of the symphysis straight), Aymberedactylus cearensis Pêgas, Leal & Kellner, 2016 (dorsally concave mandibular symphysis throughout entire extent) and Caupedactylus ybaka Kellner, 2013 (posterior half of the ventral margin of the mandibular symphysis forming a slight convex surface). It is interesting to notice that all of the listed taxa, apart from C. ybaka, are only known from a (complete or partially complete) lower jaw, such as the case of T. recki. Thus, this level of analysis regarding the shape of a specific portion of the lower jaw, or any specific bone structure from other bones, are more likely to be identified when the taxonomist can rely on (very) fragmented specimens. This seems to be quite obvious since we are “forced” to perceive the details of more incomplete material to try to reach the more inclusive taxonomic level as possible.

Another well-known problem concerning the erection of new species regards the limited sample size of fossils, which was recently addressed by Massare & Lomax (2018)MASSARE JA & LOMAX DR. 2018. Hindfins of Ichthyosaurus: effects of large sample size on ‘distinct’ morphological characters. Geol Mag: 1-20. for Ichthyosaurus. Aquatic reptiles, as pterosaurs, bear unique morphological characters and did not have living representatives or suitable analogs. The authors have evaluated if different hindfin morphology in Ichthyosaurus was of taxonomic utility in the sense of erecting new species, and argued that the sample size has “implications for identifying unique diagnostic characters (autapomorphies) based on limited fossil material”. In the case of Ichthyosaurus, if just fewer specimens would have been available, variation in hindfin morphology could have appeared less variable and more distinct. This shows that the more reduced sample size, the less variation will be recognized, which hampers morphotypes identification (Massare & Lomax 2018MASSARE JA & LOMAX DR. 2018. Hindfins of Ichthyosaurus: effects of large sample size on ‘distinct’ morphological characters. Geol Mag: 1-20.). As morphotypes are defined as different types of individuals that belong to the same species (morph), recognition of morphotypes relies upon many quite complete specimens of a species, otherwise intermediate morphologies could not be identified. Thus, unique morphologies can only be stated as such if numerous specimens can more confidently show that these are indeed taxonomically distinct characters and not a grade form within the variation. Massare & Lomax (2018)MASSARE JA & LOMAX DR. 2018. Hindfins of Ichthyosaurus: effects of large sample size on ‘distinct’ morphological characters. Geol Mag: 1-20. also call the attention for the case of isolated elements that seem to bear these particular morphologies. As these elements seem to be slightly different from other known species, and in the lack of more elements that could provide a better comparison to these same elements in different species, they are usually erected as new species.

Regarding pterosaurs, most species are erected based on one or few specimens and, as usual for fossil material, relies primarily upon morphology (although anatomical information is frequently missing). A worth mentioning case is the Pteranodon-complex, which comprises the best known pterosaurs so far and was a subject of investigation by many researchers concerning the identification of different species. This much-debated complex has been lately addressed by Kellner (2010)KELLNER AWA. 2010. Comments on the Pteranodontidae (Pterosauria, Pterodactyloidea) with the description of two new species. An Acad Bras Cienc 82: 1063-1084. https://doi.org/10.1590/S0001-37652010000400025. who re-evaluated the genus Pteranodon and erected two new species (Geosternbergia maiseyi Kellner, 2010 and Dawndraco kanzai Kellner, 2010). The author also discussed other problems besides the reduced number of specimens to define new species, such as the incompleteness of fossil material, taphonomy and the absence of modern representatives or suitable analogs. However, as abovementioned, the major issue to be considered for taxonomy in fossils is morphology, but as form and structure can vary depending on ontogeny, gender, individual differences and taphonomy (Kellner 2010KELLNER AWA. 2010. Comments on the Pteranodontidae (Pterosauria, Pterodactyloidea) with the description of two new species. An Acad Bras Cienc 82: 1063-1084. https://doi.org/10.1590/S0001-37652010000400025.), the lack of a considerable number of specimens hampers the recognition of variation as a result of one of these factors or taxonomically distinct characters. In the case of the Pteranodon-complex, although different ontogenetic stages have already been recognized by Bennett (1993)BENNETT SC. 1993. The ontogeny of Pteranodon and other pterosaurs. Paleobiology 19: 92-106. for Pteranodon, a total of 14 species have been described, 11 of which referred to Pteranodon but considered as inflated by some reviewers (Kellner 2010KELLNER AWA. 2010. Comments on the Pteranodontidae (Pterosauria, Pterodactyloidea) with the description of two new species. An Acad Bras Cienc 82: 1063-1084. https://doi.org/10.1590/S0001-37652010000400025.). Thus, fossil taxonomy can possibly be failing to reflect the real diversity and consequently biasing our view over the paleobiology of extinct taxa.

But what would be the impact in pterosaur systematics if fairly fragmented fossils are erected as new taxa?

As morphological information is essential to taxonomic studies but is constantly incomplete in fossils, which are subjected to many taphonomic and diagenetic processes (Lautenschlager 2016LAUTENSCHLAGER S. 2016. Reconstructing the past: methods and techniques for the digital restoration of fossils. R Soc Open Sci 3(10): 160342.), some pterosaur taxonomists refrain from erecting new taxa from single pieces of bone elements. However, 31 from 227 species (13.7%) are erected based on single elements: 1-5 characters are used to diagnose 24 species, 6-9 to 6 species and up to 10 characters to 1 species. From the nature of these elements, they are mostly complete or partial mandibles (n=18), and others consist of maxillae (n=4), cervical vertebrae and snout fragments (n=3 for both), humeri (n=1), premaxillae (n=1) and phalanx (n=1). The taxonomic validity of Arambourgiana philadelphiae Arambourg, 1954 (holotype UJA VF-1, cervical V lacking its posterior end), one of these species, has been questioned by Witton et al. (2010)WITTON MP, MARTILL DM & LOVERIDGE RF. 2010. Clipping the wings of giant pterosaurs: Comments on wingspan estimations and diversity. Acta Geoscientica Sinica 31: 79-81. who have proposed to synonymize it with Hatzegopteryx thambema Vremir, 2010. Indeed the misinterpretation over the mid-cervical vertebra of Arambourgiana Nessov & Jarkov, 1989 (originally described as a wing metacarpal by Arambourg (1954, 1959)) may have been induced by the difficulties in identifying a single 620 mm cylindrical cervical vertebra at the time azhdarchids were not known (and consequently neither giant pterosaurs that could have bear such elongated necks) and the lack of fully developed vertebral processes that could give an easier clue about its nature. Thus, it is understandable that a piece of bone with a circular cross-section could be attributed to a limb bone diaphysis instead of being considered an axial element.

As already mentioned, A. dehmi consists of a single first phalanx and was originally allocated into the Pterodactyloidea (and lately considered as an ornothocheiroid sensu Kellner). The extreme thickness of this phalanx pointed out by the original description of Wellnhofer (1977)WELLNHOFER P. 1977. Araripedactylus dehmi nov. gen., nov. sp., ein neuer Flugsaurier aus der Unterkreide von Brasilein. Mitteilungen der Bayerischen Staatssamlung für Palaeontologie und historische Geologie: 157-167. (not lately confirmed by Kellner & Tomida (2000)KELLNER AWA & TOMIDA Y. 2000. Description of a new species of Anhangueridae (Pterodactyloidea) with comments on the pterosaur fauna from the Santana Formation (Aptian-Albian), Northeastern Brazil. Nat Sci Mus Monogr 17: 1-135.), together with the damaged condition of its distal end, would have imposed difficulties in the identification of a plain piece of bone in the late 70’s. Also, Bogolubovia orientallis (Bogolubov 1914BOGOLUBOV NN. 1914. On a Pterodactyl Vertebra from the Upper Cretaceous Beds of the Saratov Government. Ezhegodn Geol Mineral Ross 16(1): 1-7.) described in the early XX century, was originally assigned to the genus “Ornithostoma” Seeley, 1871 and belonging to pteranodontids before having its own genus erected (Nesov & Yarkov 1989NESOV LA & YARKOV AA. 1989. New Birds from the Cretaceous–Paleogene of the USSR and Some Remarks on the History of Origin and Evolution of the Class. Tr Zool Inst Akad Nauk SSSR 197: 78-97.). The specimen, which consisted of a fragment of the posterior portion of a cervical vertebra, was lately regarded as a nomen dubium by Bakhurina and Unwin (1995), who have questioned the possibility of identification of its type material. This potential taxonomical invalidity was then refuted by Averianov et al. (2005)AVERIANOV A, ARKHANGELSKY M, PERVUSHOV E & IVANOV A. 2005. A New Record of an Azhdarchid (Pterosauria: Azhdarchidae) from the Upper Cretaceous of the Volga Region. Paleontol J 39(4): 433-439. based on the species being considerably different from other known cervical vertebrae of azhdarchids in which concerns the position of the spinal canal, the low condyle and well developed postexapophyses (Averianov et al. 2005AVERIANOV A, ARKHANGELSKY M, PERVUSHOV E & IVANOV A. 2005. A New Record of an Azhdarchid (Pterosauria: Azhdarchidae) from the Upper Cretaceous of the Volga Region. Paleontol J 39(4): 433-439.).

Taxonomic discordances have also comprised Brasileodactylus Kellner, 1984 (holotype MN 4804-V, proximal part of a mandible) firstly assigned to the Ornothocheiridae by Kellner (1984) before being more contentiously allocated in the Pterodactyloidea incertae sedis (Kellner 1991KELLNER AWA. 1991. Pterossauros do Brasil. M. Sc. Thesis, Universidade Federal do Rio de Janeiro, Rio de Janeiro, 543 p. (Unpublished).), then to have affinities to the Anhangueridae (Kellner & Tomida, 2000) and even considered to be a species of Coloborhynchus Owen, 1874 (Frey et al. 2003FREY E, MARTILL DM & BUCHY MC. 2003. A new crested ornithocheirid from the Lower Cretaceous of northeastern Brazil and the unusual death of an unusual pterosaur. Geol Soc London, Special Publications 217: 55-63.). However, a dentary sagittal groove bearing small sub-grooves and the extremely elongated mandibular symphysis when compared with that of Anhanguera, Criorhynchus Owen, 1974 and Coloborhynchus seem to be apomorphic features of Brasileodactylus (Veldmeijer et al. 2005VELDMEIJER AJ, SIGNORE M & MEIJER H. 2005. Brasileodactylus (Pterosauria, Pterodactyloidea, Anhangueridae); an update. Cranium 22(1): 45-56.). The anterior portion of the rostrum (partial mandible) of the holotype (NHMUK PV 39409) of Cimoliopterus cuvieri (Bowerbank, 1851), formerly Pterodactylus cuvieri, was lately reassigned to the genus Ornithocheirus and Coloborhynchus until Rodrigues & Kellner (2013)RODRIGUES T & KELLNER AWA. 2013. Taxonomic review of the Ornithocheirus complex (Pterosauria) from the Cretaceous of England. Zookeys 308: 1-112 have placed it in a new monotypic genus. Also, Coloborhynchus clavirostris Owen, 1874 (holotype NHMUK PV R 1822), a fragment of premaxilla and maxilla, has been synonimized with Ornithocheirus simus [=Criorhynchus simus] by Hooley (1914)HOOLEY RW. 1914. LXI.—On the Ornithosaurian genus Ornithocheirus, with a review of the specimens from the Cambridge Greensand in the Sedgwick Museum, Cambridge. J Nat Hist 13(78): 529-557., Kuhn (1967)KUHN O. 1967. Die fossile Wirbeltierklasse Pterosauria. Krailling: Oeben-Verlag, 52 p. and Wellnhofer (1978)WELLNHOFER P. 1978. Pterosauria. Handbuch der Palaeoherpetologie, Teil 19. Stuttgart: Gustav Fischer Verlag, Stuttgart, 82 p. until being revalidated by Lee (1994)LEE YN. 1994. The Early Cretaceous pterodactyloid pterosaur Coloborhynchus from North America. Palaeontology 37: 755-763. whose position was corroborated by Unwin (2001)UNWIN DM. 2001. An overview of the pterosaur assemblage from the Cambridge Greensand (Cretaceous) of Eastern England. Mitt Mus Nat kd Berl, Geowiss, Reihe 4: 189-221. and Rodrigues & Kellner (2013)RODRIGUES T & KELLNER AWA. 2013. Taxonomic review of the Ornithocheirus complex (Pterosauria) from the Cretaceous of England. Zookeys 308: 1-112. On the contrary, Lonchodectes compressirostris (formerly attributed to the genera Pterodactylus Cuvier, 1809 and Ornithocheirus), a partial maxilla also referred by Hooley (1914)HOOLEY RW. 1914. LXI.—On the Ornithosaurian genus Ornithocheirus, with a review of the specimens from the Cambridge Greensand in the Sedgwick Museum, Cambridge. J Nat Hist 13(78): 529-557. who re-introducted the genus Lonchodectes Hooley, 1914 and considered Lonchodectes compressirostris (Owen, 1851) one of the nine Lonchodectes species, was considered a valid species by Unwin (2001)UNWIN DM. 2001. An overview of the pterosaur assemblage from the Cambridge Greensand (Cretaceous) of Eastern England. Mitt Mus Nat kd Berl, Geowiss, Reihe 4: 189-221. and lately a nomen dubium by Rodrigues & Kellner (2013)RODRIGUES T & KELLNER AWA. 2013. Taxonomic review of the Ornithocheirus complex (Pterosauria) from the Cretaceous of England. Zookeys 308: 1-112. Uktenadactylus wadleighi (Lee, 1994), former Coloborhynchus wadleighi, consists of a partial snout that was reassigned to a new genus in 2009 by Kellner & Rodrigues, who had restricted the genus Coloborhynchus to the single species C. clavirostris. Another Lonchodectes species, Lonchodectes sagittirostris (Owen, 1874), consisting of a pair of lower jaws (formerly allocated to the Ornithocheirus genus), was also considered a nomen dubium by Rodrigues and Kellner (2013) and then reassigned to the genus Serradraco by Rigal et al. (2017). Indeed, the exceedingly fragmentary nature of the Cambridge Greensand pterosaurs made their systematic a constantly disputed taxonomic question over a decade until Rodrigues and Kellner (2013) have extensively reviewed the Ornithocheirus complex and discussed many ornithocheirids in the light of the revised taxonomy.

Even Siroccopteryx moroccensis Mader & Kellner, 1999, only known from the front portion of the mandible, had its genus considered as a junior synonym of Coloborhynchus by Unwin (2001)UNWIN DM. 2001. An overview of the pterosaur assemblage from the Cambridge Greensand (Cretaceous) of Eastern England. Mitt Mus Nat kd Berl, Geowiss, Reihe 4: 189-221. by the resemblance of this genus to a specimen of Coloborhynchus described by Lee (1994)LEE YN. 1994. The Early Cretaceous pterodactyloid pterosaur Coloborhynchus from North America. Palaeontology 37: 755-763. and closely related to Anhanguera by Fastnatch (2001). Rodrigues & Kellner (2009)RODRIGUES T & KELLNER AWA. 2009. Review of the pterosaur pterodactyloid Coloborhynchus. Zitteliana B 28: 219-228. have then considered Siroccopteryx a distinct genus.

As abovementioned, 13.7% of all pterosaur species were erected based on single elements. According to Massare & Lomax (2018)MASSARE JA & LOMAX DR. 2018. Hindfins of Ichthyosaurus: effects of large sample size on ‘distinct’ morphological characters. Geol Mag: 1-20., isolated or fragmentary elements lack plentiful information to justify the erection of new taxon, and in the absence of several specimens it is not possible to properly identify whether what appear to be unique morphologies are indeed taxonomically distinct characters or intermediate forms within the variation. Therefore, it is not possible to know if the erection of these species is justified, especially in the lack of a more deepened and detailed taxonomic study, until other studies challenge these nominations by critically re-examining these species. This frequently poses a major problem concerning the discard of previously accepted taxonomic names by synonymization or the proposal of nomina dubia. This current procedure makes an effort to minimize taxonomic inflation (i.e., inflation of species names) when individual parts being described as separate species are shown to be problematic. As above exemplified, this is also a major concern when it comes to pterosaurs, with several species being constantly challenged.

Another problem of increasing species-level taxa based on limited fossils is the increased diversity bias. Taxonomic inflation is more critical when taxa have a fragmentary and sparse fossil record (Uhen & Pyenson 2007UHEN MD & PYENSON ND. 2007. Diversity estimates, biases, and historiographic effects: resolving cetacean diversity in the Tertiary. Palaeontol Electron 10(2): 11A-22.). However, it is noteworthy that sometimes the description of new taxa based solely on complete specimens may also bias diversity, but differently from what is expected when dealing with incomplete specimens (Donovan 2001DONOVAN SK. 2001. Evolution of Caribbean echinoderms during the Cenozoic: moving towards a complete picture using all of the fossils. Palaeogeogr Palaeoclimatol Palaeoecol 166: 177-192.). Thus, if diversity bias can occur even when complete specimens are described, this cannot be an argument to prevent limited specimens to be erected as new taxa.

Notwithstanding, although numerous problems are related to naming species based on incomplete and fragmentary material, many type specimens are incomplete but diagnostic in vertebrate paleontology (Uhen & Pyenson 2007UHEN MD & PYENSON ND. 2007. Diversity estimates, biases, and historiographic effects: resolving cetacean diversity in the Tertiary. Palaeontol Electron 10(2): 11A-22.). We thus refrain from advocating against this practice despite these potential problems, but suggest being particularly cautious when species-level taxa are erected based on limited and/or isolated material. In the case of pterosaurs, as already mentioned, potential taxonomic problems could be avoided if diagnostic features are mapped with cautious by a broad and deep taxonomic study also based on as many comparisons with other material as possible. Along with that, current research practices can help, such as reproducing high-resolution photographs in descriptive research articles and publishing informative figures, which enables better anatomical comparisons to be done.

How many pterosaur genera are still unknown?

One of the major substantial challenges in Paleontology is to quantify the diversity of animal groups (Alroy et al. 2001ALROY J ET AL. 2001. Effects of sampling standardization on estimates of Phanerozoic marine diversification. Proc Natl Acad Sci USA 98: 6261-6266.), and despite some punctual efforts on quantifying some of these groups (e.g., the diversity of dinosaurs; Dodson 1990DODSON P. 1990. Counting dinosaurs: How many kinds were there? Proc Natl Acad Sci USA 87: 7608-12., Russell 1995RUSSELL DA. 1995. China and the lost worlds of the dinosaurian era. Histor Biol 10(1): 3-12., Wang & Dodson 2006WANG SC & DODSON P. 2006. Estimating the diversity of dinosaurs. Proc Natl Acad Sci USA 103(37): 13601-13605.), studies of this kind are still scarce. The well-known incompleteness of the fossil record, as well as taxonomic difficulties, indeed hampers the diversity estimation of fossil groups (Wang & Dodson 2006WANG SC & DODSON P. 2006. Estimating the diversity of dinosaurs. Proc Natl Acad Sci USA 103(37): 13601-13605.). Research on particularly estimating the pterosaur diversity also follows this pattern, with few studies having been performed so far (e.g., Butler et al. 2009BUTLER RJ, BARRETT PM & GOWER DJ. 2009. Postcracial skeletal pneumaticity and air-sacs in the earliest pterosaurs. Biology Letters 5: 557-560., 2012, 2013).

There are 189 valid pterosaur genera up to now. Although a deep analysis on pterosaur diversity using different approaches is beyond the scope of this paper, we have estimated it by using the ACE model to reach a result for the generic pterosaur diversity of 807, which means that 23.4% of the pterosaur genera are currently known. Because of the small sample sizes from the Late Triassic to the Mid Jurassic, estimation for these periods are very unreliable (Table I). These data allowed us to predict the rate of future pterosaur discoveries by fitting a logistic accumulation curve to the cumulative counts of known genera throughout the years using the estimation of pterosaur diversity as the point where the curve becomes an asymptote. This curve indicates that near 2060 about half of the pterosaur diversity will be known, and predicts that 90% of this diversity will have been unveiled up to 2145 (Figure 9).

Figure 9
Rate of future pterosaur discoveries using a logistic accumulation curve of the form y=807/(1+806*e^(-0, 0.026026*t)). The dotted line represents the estimated curve, and the solid line corresponds to the known growth.

From 2000 to 2019, 116 genera were described, which means that in those two decades on average 6.11 new genera are described per year. The prediction that 90% of the generic richness will be known in 2145 requires 5.5 new genera to be described per year, or that in a bit more than a century, 540 new genera need to be described.

The number of 807 genera is especially low for the entire Mesozoic when compared to the current diversity of flying vertebrates, and to the diversity of land vertebrates of the time. Neornithes, a group that includes all living birds, is presently the most diverse clade of present-day vertebrates that is widespread to roughly all ecological niches (Gill 2007GILL FB. 2007. Ornithology, 3rd ed., New York: W. H. Freeman.), and bats (order Chiroptera) account for ~ 20% of mammal diversity, which make these modern flying vertebrates one of the largest monophyletic mammalian clades (Lei & Dong 2016LEI M & DONG D. 2016. Phylogenomic analyses of bat subordinal relationships based on transcriptome data. Sci Rep 6: 27726.). It is estimated that 88% of bats that ever existed did not enter the fossil record (Eiting & Gunnell 2009EITING T & GUNNELL G. 2009. Global Completeness of the Bat Fossil Record. J Mamm Evol 16: 151-173.), and the similarity of Character Completeness Metric (CCM) records for pterosaurs, extinct chiropterans and birds are probably due to similar taphonomic bias related to their resembling ecologies (Dean et al. 2016DEAN CD, MANNION PD & BUTLER RJ. 2016. Preservational bias controls the fossil record of pterosaurs. Palaeontology 59: 225-247., Brocklehurst et al. 2012BROCKLEHURST N, UPCHURCH P, MANNION PD & O’CONNOR J. 2012. The Completeness of the Fossil Record of Mesozoic Birds: Implications for Early Avian Evolution. PLOS ONE 7(6): e39056., Brown et al. 2019BROWN EE, CASHMORE DD, SIMMONS NB & BUTLER RJ. 2019. Quantifying the completeness of the bat fossil record. Palaeontology 62(5): 757-776.). Thus, a low percentage of the pterosaurs that ever existed is also expected.

CONCLUSIONS

The level of taxonomic identification relies on which parts of the morphology are preserved, and how complete they are. Analyzed data showed that 31 from 227 pterosaur species (13.7%) are erected based on single elements that are mostly complete or partial mandibles (n=18). Selection of characters relies on how deep is our taxonomic approach as we mainly deal with combination of morphological characters to advocate species recognition, but the lack of a critical approach to erect new taxa without sufficient comparison with other species and/or an extensive review may lead to inadequate taxonomic results. The fragmentary nature of some fossils can also raise doubts on the validity of the erected species and could be avoided by a more deepened and detailed taxonomic study. Finally the limited sample size of fossils hampers the recognition of morphotypes and thus intermediate morphologies could not be identified. Despite all these problems, we refrain from advocating against the erection of new taxa based on limited and/or isolated material, but suggest being particularly cautious when species-level taxa are erected. Moreover, since some deposits will provide mostly fragmented and incomplete fossil material (as many type specimens are incomplete but diagnostic in vertebrate paleontology), as far as the requirements of a broad and cautious revision of genus/group are properly undertaken, the assignment of these fairly incomplete specimens to the most inclusive taxonomic level is feasible.

We still have much more than half of the estimated pterosaur genera to discover (more specifically, 77.9% is yet to be discovered), which justify the continuous effort of unveiling this diversity by describing new taxa, even though if we account for single, very fragmented material (together with deepening the taxonomic level of investigation). As this statistical survey regarding the nature and number of the osteological structures that use to define new pterosaur taxa has never been made before, tracing this scenario has the potential to guide future works on the description of new pterosaur taxa.

ACKNOWLEDGMENTS

FRC want to thank Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq, grant number 421772/2018-2) for financial support.

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BAKHURINA NN & UNWIN DM. 1995. A Survey of Pterosaurs from the Jurassic and Cretaceous of the Former Soviet Union and Mongolia. Histor Biol 10(1): 197-245.
BENNETT SC. 1992. Sexual dimorphism of Pteranodon and other pterosaurs, with comments on Bennett SC. 2000. “Inferring stratigraphic position of fossil vertebrates from the Niobrara Chalk of western Kansas.” Kansas Geol Survey Bull 244(1): 26.
BENNETT SC. 1993. The ontogeny of Pteranodon and other pterosaurs. Paleobiology 19: 92-106.
BENNETT SC 2000. Inferring stratigraphic position of fossil vertebrates from the Niobrara Chalk of western Kansas. Curr Res Earth Sci, Kansas Geological Survey Bulletin, 244(Part 1), 26 p.
BOGOLUBOV NN. 1914. On a Pterodactyl Vertebra from the Upper Cretaceous Beds of the Saratov Government. Ezhegodn Geol Mineral Ross 16(1): 1-7.
BROCKLEHURST N, UPCHURCH P, MANNION PD & O’CONNOR J. 2012. The Completeness of the Fossil Record of Mesozoic Birds: Implications for Early Avian Evolution. PLOS ONE 7(6): e39056.
BROWN EE, CASHMORE DD, SIMMONS NB & BUTLER RJ. 2019. Quantifying the completeness of the bat fossil record. Palaeontology 62(5): 757-776.
BUTLER RJ, BARRETT PM & GOWER DJ. 2009. Postcracial skeletal pneumaticity and air-sacs in the earliest pterosaurs. Biology Letters 5: 557-560.
BUTLER RJ, BARRETT PM & GOWER DJ. 2012. Reassessment of the evidence for postcranial skeletal pneumaticity in Triassic archosaurs, and the early evolution of the avian respiratory system. PLoS ONE 7(3): e34094.
BUTLER RJ, BENSON RB & BARRETT PM. 2013. Pterosaur diversity: untangling the influence of sampling biases, Lagerstätten, and genuine biodiversity signals. Palaeogeogr Palaeoclimatol Palaeoecol 372: 78-87.
CHAO A & LEE SM. 1992. Estimating the number of classes via sample coverage. J Am Sta Assoc 87: 210-217.
CHAO A & YANG MC. 1993. Stopping rules and estimation for recapture debugging with unequal failure rates. Biometrika 80: 193-201.
CHENG X, JIANG SX, WANG XL & KELLNER AWA. 2016. New information on the Wukongopteridae (Pterosauria) revealed by a new specimen from the Jurassic of China. PeerJ 4: e2177.
CIFELLI RL & KIELAN-JAWOROWSKA Z. 2005. Diagnosis: Differing interpretations of the ICZN. Acta Palaeontol Polon 50: 650-652.
COOK LG, EDWARDS RD, CRISP MD & HARDY NB. 2010. Need morphology always be required for new species descriptions? Invertebr Syst 24: 322-326.
DEAN CD, MANNION PD & BUTLER RJ. 2016. Preservational bias controls the fossil record of pterosaurs. Palaeontology 59: 225-247.
DODSON P. 1990. Counting dinosaurs: How many kinds were there? Proc Natl Acad Sci USA 87: 7608-12.
DONOVAN SK. 2001. Evolution of Caribbean echinoderms during the Cenozoic: moving towards a complete picture using all of the fossils. Palaeogeogr Palaeoclimatol Palaeoecol 166: 177-192.
DUBOIS A. 2017. Diagnoses in zoological taxonomy and nomenclature. Bionomina 12: 63-85.
EBACH MC & HOLDREGE C. 2005a. More taxonomy, not DNA barcoding. BioScience 55: 822-823.
EBACH MC & HOLDREGE C. 2005b. DNA barcoding is no substitute for taxonomy. Nature 434: 697.
EITING T & GUNNELL G. 2009. Global Completeness of the Bat Fossil Record. J Mamm Evol 16: 151-173.
FOREY PL, FORTEY RA, KENRICK P & SMITH AB. 2004. Taxonomy and fossils: a critical appraisal. Phil Trans R Soc Lond B 359: 639-653.
FREY E, MARTILL DM & BUCHY MC. 2003. A new crested ornithocheirid from the Lower Cretaceous of northeastern Brazil and the unusual death of an unusual pterosaur. Geol Soc London, Special Publications 217: 55-63.
FRöBISCH NB & FRöBISCH J. 2006. A new basal pterosaur genus from the upper Triassic of the Northern Calcareous Alps of Switzerland. Palaeontology 49(5): 1081-1090.
GILL FB. 2007. Ornithology, 3rd ed., New York: W. H. Freeman.
HEADDEN JA & CAMPOS HBN. 2014. An unusual edentulous pterosaur from the Early Cretaceous Romualdo Formation of Brazil. Histor Biol 27: 815-826.
HOOLEY RW. 1914. LXI.—On the Ornithosaurian genus Ornithocheirus, with a review of the specimens from the Cambridge Greensand in the Sedgwick Museum, Cambridge. J Nat Hist 13(78): 529-557.
HUELSENBECK JP. 1991. When are fossils better than extant taxa in phylogenetic analysis? Syst Zool 40: 458-469.
JOLLIFFE IT. 2002. Principal Component Analysis, Series: Springer Series in Statistics, 2nd ed., New York: Springer, 487 p.
JOLLIFFE IT & CADIMA J. 2016. Principal component analysis: a review and recent developments. Philos Trans R Soc A 374: 20150202. http://dx.doi.org/10.1098/rsta.2015.0202.
KELLNER AWA. 1991. Pterossauros do Brasil. M. Sc. Thesis, Universidade Federal do Rio de Janeiro, Rio de Janeiro, 543 p. (Unpublished).
KELLNER AWA. 2010. Comments on the Pteranodontidae (Pterosauria, Pterodactyloidea) with the description of two new species. An Acad Bras Cienc 82: 1063-1084. https://doi.org/10.1590/S0001-37652010000400025.
KELLNER AWA, MARTINS AMS & FORD TL. 2007. A survey of pterosaurs from Africa with the description of a new specimen from Morocco. In: Carvalho IS et al. (Eds), Paleontologia. Cenários de Vida 1, p. 257-267.
KELLNER AWA, RODRIGUES T & COSTA FR. 2011. Short note on a pteranodontoid pterosaur (Pterodactyloidea) from western Queensland, Australia. An Acad Bras Cienc 83: 301-308. https://doi.org/10.1590/S0001-37652011000100018.
KELLNER AWA & TOMIDA Y. 2000. Description of a new species of Anhangueridae (Pterodactyloidea) with comments on the pterosaur fauna from the Santana Formation (Aptian-Albian), Northeastern Brazil. Nat Sci Mus Monogr 17: 1-135.
KOMAREK A & BEUTEL RG. 2006. Problems in taxonomy and suggestions for a standardized description of new insect taxa. Entomol Prob 36(2): 55-70.
KREBS CJ. 1999. Ecological Methodology. Menlo Park, Addison Wesley Educational Publishers, 620 p.
KUHN O. 1967. Die fossile Wirbeltierklasse Pterosauria. Krailling: Oeben-Verlag, 52 p.
LAUTENSCHLAGER S. 2016. Reconstructing the past: methods and techniques for the digital restoration of fossils. R Soc Open Sci 3(10): 160342.
LEE YN. 1994. The Early Cretaceous pterodactyloid pterosaur Coloborhynchus from North America. Palaeontology 37: 755-763.
LEI M & DONG D. 2016. Phylogenomic analyses of bat subordinal relationships based on transcriptome data. Sci Rep 6: 27726.
LÜ JC, GAO YB, XING LD, LI ZX & JI Q. 2007. A New Species of Huaxiapterus (Pterosauria: Tapejaridae) from the Early Cretaceous of Western Liaoning, China. Acta Geol Sin Engl 81: 683-687.
LÜ JC, JIN XS, UNWIN DM, ZHAO LJ, AZUMA Y & JI Q. 2006. A new species of Huaxiapterus (Pterosauria: Pterodactyloidea）from the Lower Cretaceous of western Liaoning, China with comments on the systematics of tapejarid pterosaurs. Acta Geol Sin 80: 315-326.
LÜ JC, TENG FF, SUN DY, SHEN CZ, LI GQ, GAO X & LIU HF. 2016. The toothless pterosaurs from China. Acta Geol Sin 90: 2513-2525.
LÜ JC, MENG QJ, WANG PB, LIU D, SHEN CZ & ZHANG YG. 2017. Short note on a new anurognathid pterosaur with evidence of perching behaviour from Jianchang of Liaoning Province, China. Geol Soc London, Special Publications 455: 95-104.
MANZIG PM, KELLNER AWA, WEINSCHUTZ LC, FRAGOSO CE, VEGA CS, GUIMARÃES GB, GODOY LC, LICCARDO A, RICETTI JHZ & MOURA CC. 2014. Discovery of a Rare Pterosaur Bone Bed in a Cretaceous Desert with Insights on Ontogeny and Behavior of Flying Reptiles. PLoS ONE 9(8): e100005.
MASSARE JA & LOMAX DR. 2018. Hindfins of Ichthyosaurus: effects of large sample size on ‘distinct’ morphological characters. Geol Mag: 1-20.
NESSOV LA. 1984. Upper Cretaceous pterosaurs and birds from central Asia. Paleontol J 1984(1): 38-49.
NESOV LA & YARKOV AA. 1989. New Birds from the Cretaceous–Paleogene of the USSR and Some Remarks on the History of Origin and Evolution of the Class. Tr Zool Inst Akad Nauk SSSR 197: 78-97.
NIELSEN F. 2016. Hierarchical Clustering. In: Introduction to HPC with MPI for data science. Springer International Publishing.
NIXON KC & WHEELER QD. 1990. An amplification of the phylogenetic species concept. Cladistics 6(3): 211-223.
O’SULLIVAN M & MARTILL DM. 2015. Evidence for the presence of Rhamphorhynchus (Pterosauria: Rhamphorhynchinae) in the Kimmeridge Clay of the UK. P Geologist Assoc 126(3): 390-401.
PACKER L, GIBBS J, SHEFFIELD C & HANNER R. 2009. DNA barcoding and the mediocrity of morphology. Mol Ecol Resour 9: 42-50.
PÊGAS RV, COSTA FR & KELLNER AWA. 2018. New information on the osteology and a taxonomic revision of the genus Thalassodromeus (Pterodactyloidea, Tapejaridae, Thalassodrominae). J Vert Paleontol 38(2): e1443273.
PINHEIRO FL & RODRIGUES T. 2017. Anhanguera taxonomy revisited: is our understanding of Santana Group pterosaur diversity biased by poor biological and stratigraphic control? PeerJ 5: e3285.
RIGAL S, MARTILL DM & SWEETMAN SC. 2017. A new pterosaur specimen from the Upper Tunbridge Wells Sand Formation (Cretaceous, Valanginian) of southern England and a review of Lonchodectes sagittirostris (Owen 1874). Geol Soc London, Special Publications 455: 221-232.
RODRIGUES T & KELLNER AWA. 2009. Review of the pterosaur pterodactyloid Coloborhynchus. Zitteliana B 28: 219-228.
RODRIGUES T & KELLNER AWA. 2013. Taxonomic review of the Ornithocheirus complex (Pterosauria) from the Cretaceous of England. Zookeys 308: 1-112
RUSSELL DA. 1995. China and the lost worlds of the dinosaurian era. Histor Biol 10(1): 3-12.
SCHWENTNER M, TIMMS BV & RICHTER S. 2011. An integrative approach to species delineation incorporating different species concepts: a case study of Limnadopsis (Branchiopoda: Spinicaudata). Biol J Linn Soc 104: 575-599.
SOKAL M 1958. A statistical method for evaluating systematic relationships. Univ Kans sci bull 38: 1409-1438.
UHEN MD & PYENSON ND. 2007. Diversity estimates, biases, and historiographic effects: resolving cetacean diversity in the Tertiary. Palaeontol Electron 10(2): 11A-22.
UNWIN DM. 2001. An overview of the pterosaur assemblage from the Cambridge Greensand (Cretaceous) of Eastern England. Mitt Mus Nat kd Berl, Geowiss, Reihe 4: 189-221.
VELDMEIJER AJ, SIGNORE M & MEIJER H. 2005. Brasileodactylus (Pterosauria, Pterodactyloidea, Anhangueridae); an update. Cranium 22(1): 45-56.
WANG SC & DODSON P. 2006. Estimating the diversity of dinosaurs. Proc Natl Acad Sci USA 103(37): 13601-13605.
WELLNHOFER P. 1977. Araripedactylus dehmi nov. gen., nov. sp., ein neuer Flugsaurier aus der Unterkreide von Brasilein. Mitteilungen der Bayerischen Staatssamlung für Palaeontologie und historische Geologie: 157-167.
WELLNHOFER P. 1978. Pterosauria. Handbuch der Palaeoherpetologie, Teil 19. Stuttgart: Gustav Fischer Verlag, Stuttgart, 82 p.
WIENS JJ. 2003. Missing data, incomplete taxa, and phylogenetic accuracy. Syst Biol 52: 528-538.
WIENS JJ & REEDER TW. 1995. Combining data sets with different numbers of taxa for phylogenetic analysis. Syst Biol 44: 548-558
WILLMANN R. & MEIER R. 2000. A critique from the Hennigian species concept perspective. In: Wheeler QD & Meier R (Eds), Species concepts and phylogenetic theory: a debate. Columbia University Press, New York, p.101-118.
WITTON MP, MARTILL DM & LOVERIDGE RF. 2010. Clipping the wings of giant pterosaurs: Comments on wingspan estimations and diversity. Acta Geoscientica Sinica 31: 79-81.
ZAMBELLI R. 1973. Eudimorphodon ranzii gen. nov., sp. nov., uno pterosauro Triassico. Rendiconti Scienze di Instituto Lombardo B 107: 27-32.

Publication Dates

Publication in this collection
20 Sept 2021
Date of issue
2021

History

Received
5 Oct 2020
Accepted
23 Mar 2021

This is an open-access article distributed under the terms of the Creative Commons Attribution License

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[12] BOGOLUBOV NN. 1914. On a Pterodactyl Vertebra from the Upper Cretaceous Beds of the Saratov Government. Ezhegodn Geol Mineral Ross 16(1): 1-7.

[13] BROCKLEHURST N, UPCHURCH P, MANNION PD & O’CONNOR J. 2012. The Completeness of the Fossil Record of Mesozoic Birds: Implications for Early Avian Evolution. PLOS ONE 7(6): e39056.

[14] BROWN EE, CASHMORE DD, SIMMONS NB & BUTLER RJ. 2019. Quantifying the completeness of the bat fossil record. Palaeontology 62(5): 757-776.

[15] BUTLER RJ, BARRETT PM & GOWER DJ. 2009. Postcracial skeletal pneumaticity and air-sacs in the earliest pterosaurs. Biology Letters 5: 557-560.

[16] BUTLER RJ, BARRETT PM & GOWER DJ. 2012. Reassessment of the evidence for postcranial skeletal pneumaticity in Triassic archosaurs, and the early evolution of the avian respiratory system. PLoS ONE 7(3): e34094.

[17] BUTLER RJ, BENSON RB & BARRETT PM. 2013. Pterosaur diversity: untangling the influence of sampling biases, Lagerstätten, and genuine biodiversity signals. Palaeogeogr Palaeoclimatol Palaeoecol 372: 78-87.

[18] CHAO A & LEE SM. 1992. Estimating the number of classes via sample coverage. J Am Sta Assoc 87: 210-217.

[19] CHAO A & YANG MC. 1993. Stopping rules and estimation for recapture debugging with unequal failure rates. Biometrika 80: 193-201.

[20] CHENG X, JIANG SX, WANG XL & KELLNER AWA. 2016. New information on the Wukongopteridae (Pterosauria) revealed by a new specimen from the Jurassic of China. PeerJ 4: e2177.

[21] CIFELLI RL & KIELAN-JAWOROWSKA Z. 2005. Diagnosis: Differing interpretations of the ICZN. Acta Palaeontol Polon 50: 650-652.

[22] COOK LG, EDWARDS RD, CRISP MD & HARDY NB. 2010. Need morphology always be required for new species descriptions? Invertebr Syst 24: 322-326.

[23] DEAN CD, MANNION PD & BUTLER RJ. 2016. Preservational bias controls the fossil record of pterosaurs. Palaeontology 59: 225-247.

[24] DODSON P. 1990. Counting dinosaurs: How many kinds were there? Proc Natl Acad Sci USA 87: 7608-12.

[25] DONOVAN SK. 2001. Evolution of Caribbean echinoderms during the Cenozoic: moving towards a complete picture using all of the fossils. Palaeogeogr Palaeoclimatol Palaeoecol 166: 177-192.

[26] DUBOIS A. 2017. Diagnoses in zoological taxonomy and nomenclature. Bionomina 12: 63-85.

[27] EBACH MC & HOLDREGE C. 2005a. More taxonomy, not DNA barcoding. BioScience 55: 822-823.

[28] EBACH MC & HOLDREGE C. 2005b. DNA barcoding is no substitute for taxonomy. Nature 434: 697.

[29] EITING T & GUNNELL G. 2009. Global Completeness of the Bat Fossil Record. J Mamm Evol 16: 151-173.

[30] FOREY PL, FORTEY RA, KENRICK P & SMITH AB. 2004. Taxonomy and fossils: a critical appraisal. Phil Trans R Soc Lond B 359: 639-653.

[31] FREY E, MARTILL DM & BUCHY MC. 2003. A new crested ornithocheirid from the Lower Cretaceous of northeastern Brazil and the unusual death of an unusual pterosaur. Geol Soc London, Special Publications 217: 55-63.

[32] FRöBISCH NB & FRöBISCH J. 2006. A new basal pterosaur genus from the upper Triassic of the Northern Calcareous Alps of Switzerland. Palaeontology 49(5): 1081-1090.

[33] GILL FB. 2007. Ornithology, 3rd ed., New York: W. H. Freeman.

[34] HEADDEN JA & CAMPOS HBN. 2014. An unusual edentulous pterosaur from the Early Cretaceous Romualdo Formation of Brazil. Histor Biol 27: 815-826.

[35] HOOLEY RW. 1914. LXI.—On the Ornithosaurian genus Ornithocheirus, with a review of the specimens from the Cambridge Greensand in the Sedgwick Museum, Cambridge. J Nat Hist 13(78): 529-557.

[36] HUELSENBECK JP. 1991. When are fossils better than extant taxa in phylogenetic analysis? Syst Zool 40: 458-469.

[37] JOLLIFFE IT. 2002. Principal Component Analysis, Series: Springer Series in Statistics, 2nd ed., New York: Springer, 487 p.

[38] JOLLIFFE IT & CADIMA J. 2016. Principal component analysis: a review and recent developments. Philos Trans R Soc A 374: 20150202. http://dx.doi.org/10.1098/rsta.2015.0202.

[39] KELLNER AWA. 1991. Pterossauros do Brasil. M. Sc. Thesis, Universidade Federal do Rio de Janeiro, Rio de Janeiro, 543 p. (Unpublished).

[40] KELLNER AWA. 2010. Comments on the Pteranodontidae (Pterosauria, Pterodactyloidea) with the description of two new species. An Acad Bras Cienc 82: 1063-1084. https://doi.org/10.1590/S0001-37652010000400025.

[41] KELLNER AWA, MARTINS AMS & FORD TL. 2007. A survey of pterosaurs from Africa with the description of a new specimen from Morocco. In: Carvalho IS et al. (Eds), Paleontologia. Cenários de Vida 1, p. 257-267.

[42] KELLNER AWA, RODRIGUES T & COSTA FR. 2011. Short note on a pteranodontoid pterosaur (Pterodactyloidea) from western Queensland, Australia. An Acad Bras Cienc 83: 301-308. https://doi.org/10.1590/S0001-37652011000100018.

[43] KELLNER AWA & TOMIDA Y. 2000. Description of a new species of Anhangueridae (Pterodactyloidea) with comments on the pterosaur fauna from the Santana Formation (Aptian-Albian), Northeastern Brazil. Nat Sci Mus Monogr 17: 1-135.

[44] KOMAREK A & BEUTEL RG. 2006. Problems in taxonomy and suggestions for a standardized description of new insect taxa. Entomol Prob 36(2): 55-70.

[45] KREBS CJ. 1999. Ecological Methodology. Menlo Park, Addison Wesley Educational Publishers, 620 p.

[46] KUHN O. 1967. Die fossile Wirbeltierklasse Pterosauria. Krailling: Oeben-Verlag, 52 p.

[47] LAUTENSCHLAGER S. 2016. Reconstructing the past: methods and techniques for the digital restoration of fossils. R Soc Open Sci 3(10): 160342.

[48] LEE YN. 1994. The Early Cretaceous pterodactyloid pterosaur Coloborhynchus from North America. Palaeontology 37: 755-763.

[49] LEI M & DONG D. 2016. Phylogenomic analyses of bat subordinal relationships based on transcriptome data. Sci Rep 6: 27726.

[50] LÜ JC, GAO YB, XING LD, LI ZX & JI Q. 2007. A New Species of Huaxiapterus (Pterosauria: Tapejaridae) from the Early Cretaceous of Western Liaoning, China. Acta Geol Sin Engl 81: 683-687.

[51] LÜ JC, JIN XS, UNWIN DM, ZHAO LJ, AZUMA Y & JI Q. 2006. A new species of Huaxiapterus (Pterosauria: Pterodactyloidea）from the Lower Cretaceous of western Liaoning, China with comments on the systematics of tapejarid pterosaurs. Acta Geol Sin 80: 315-326.

[52] LÜ JC, TENG FF, SUN DY, SHEN CZ, LI GQ, GAO X & LIU HF. 2016. The toothless pterosaurs from China. Acta Geol Sin 90: 2513-2525.

[53] LÜ JC, MENG QJ, WANG PB, LIU D, SHEN CZ & ZHANG YG. 2017. Short note on a new anurognathid pterosaur with evidence of perching behaviour from Jianchang of Liaoning Province, China. Geol Soc London, Special Publications 455: 95-104.

[54] MANZIG PM, KELLNER AWA, WEINSCHUTZ LC, FRAGOSO CE, VEGA CS, GUIMARÃES GB, GODOY LC, LICCARDO A, RICETTI JHZ & MOURA CC. 2014. Discovery of a Rare Pterosaur Bone Bed in a Cretaceous Desert with Insights on Ontogeny and Behavior of Flying Reptiles. PLoS ONE 9(8): e100005.

[55] MASSARE JA & LOMAX DR. 2018. Hindfins of Ichthyosaurus: effects of large sample size on ‘distinct’ morphological characters. Geol Mag: 1-20.

[56] NESSOV LA. 1984. Upper Cretaceous pterosaurs and birds from central Asia. Paleontol J 1984(1): 38-49.

[57] NESOV LA & YARKOV AA. 1989. New Birds from the Cretaceous–Paleogene of the USSR and Some Remarks on the History of Origin and Evolution of the Class. Tr Zool Inst Akad Nauk SSSR 197: 78-97.

[58] NIELSEN F. 2016. Hierarchical Clustering. In: Introduction to HPC with MPI for data science. Springer International Publishing.

[59] NIXON KC & WHEELER QD. 1990. An amplification of the phylogenetic species concept. Cladistics 6(3): 211-223.

[60] O’SULLIVAN M & MARTILL DM. 2015. Evidence for the presence of Rhamphorhynchus (Pterosauria: Rhamphorhynchinae) in the Kimmeridge Clay of the UK. P Geologist Assoc 126(3): 390-401.

[61] PACKER L, GIBBS J, SHEFFIELD C & HANNER R. 2009. DNA barcoding and the mediocrity of morphology. Mol Ecol Resour 9: 42-50.

[62] PÊGAS RV, COSTA FR & KELLNER AWA. 2018. New information on the osteology and a taxonomic revision of the genus Thalassodromeus (Pterodactyloidea, Tapejaridae, Thalassodrominae). J Vert Paleontol 38(2): e1443273.

[63] PINHEIRO FL & RODRIGUES T. 2017. Anhanguera taxonomy revisited: is our understanding of Santana Group pterosaur diversity biased by poor biological and stratigraphic control? PeerJ 5: e3285.

[64] RIGAL S, MARTILL DM & SWEETMAN SC. 2017. A new pterosaur specimen from the Upper Tunbridge Wells Sand Formation (Cretaceous, Valanginian) of southern England and a review of Lonchodectes sagittirostris (Owen 1874). Geol Soc London, Special Publications 455: 221-232.

[65] RODRIGUES T & KELLNER AWA. 2009. Review of the pterosaur pterodactyloid Coloborhynchus. Zitteliana B 28: 219-228.

[66] RODRIGUES T & KELLNER AWA. 2013. Taxonomic review of the Ornithocheirus complex (Pterosauria) from the Cretaceous of England. Zookeys 308: 1-112

[67] RUSSELL DA. 1995. China and the lost worlds of the dinosaurian era. Histor Biol 10(1): 3-12.

[68] SCHWENTNER M, TIMMS BV & RICHTER S. 2011. An integrative approach to species delineation incorporating different species concepts: a case study of Limnadopsis (Branchiopoda: Spinicaudata). Biol J Linn Soc 104: 575-599.

[69] SOKAL M 1958. A statistical method for evaluating systematic relationships. Univ Kans sci bull 38: 1409-1438.

[70] UHEN MD & PYENSON ND. 2007. Diversity estimates, biases, and historiographic effects: resolving cetacean diversity in the Tertiary. Palaeontol Electron 10(2): 11A-22.

[71] UNWIN DM. 2001. An overview of the pterosaur assemblage from the Cambridge Greensand (Cretaceous) of Eastern England. Mitt Mus Nat kd Berl, Geowiss, Reihe 4: 189-221.

[72] VELDMEIJER AJ, SIGNORE M & MEIJER H. 2005. Brasileodactylus (Pterosauria, Pterodactyloidea, Anhangueridae); an update. Cranium 22(1): 45-56.

[73] WANG SC & DODSON P. 2006. Estimating the diversity of dinosaurs. Proc Natl Acad Sci USA 103(37): 13601-13605.

[74] WELLNHOFER P. 1977. Araripedactylus dehmi nov. gen., nov. sp., ein neuer Flugsaurier aus der Unterkreide von Brasilein. Mitteilungen der Bayerischen Staatssamlung für Palaeontologie und historische Geologie: 157-167.

[75] WELLNHOFER P. 1978. Pterosauria. Handbuch der Palaeoherpetologie, Teil 19. Stuttgart: Gustav Fischer Verlag, Stuttgart, 82 p.

[76] WIENS JJ. 2003. Missing data, incomplete taxa, and phylogenetic accuracy. Syst Biol 52: 528-538.

[77] WIENS JJ & REEDER TW. 1995. Combining data sets with different numbers of taxa for phylogenetic analysis. Syst Biol 44: 548-558

[78] WILLMANN R. & MEIER R. 2000. A critique from the Hennigian species concept perspective. In: Wheeler QD & Meier R (Eds), Species concepts and phylogenetic theory: a debate. Columbia University Press, New York, p.101-118.

[79] WITTON MP, MARTILL DM & LOVERIDGE RF. 2010. Clipping the wings of giant pterosaurs: Comments on wingspan estimations and diversity. Acta Geoscientica Sinica 31: 79-81.

[80] ZAMBELLI R. 1973. Eudimorphodon ranzii gen. nov., sp. nov., uno pterosauro Triassico. Rendiconti Scienze di Instituto Lombardo B 107: 27-32.

Period	Known diversity	Estimated diversity	Percentage known
Entire Mesosoic	189	807	23.4%
Late Triassic	13	25	52.0%
Early Jurassic	5	6	89.3%
Mid Jurassic	15	35	42.5%
Late Jurassic	38	141	27.0%
Early Cretaceous	82	396	20.7%
Late Cretaceous	43	196	22.0%