Living cockroach genus Anaplecta discovered in Chiapas amber (Blattaria: Ectobiidae: Anaplecta vega sp.n.)

Cenozoic cockroaches are recent and with two indigenous exceptions, based on their fragmentary preservation state, they cannot be discriminated formally from representatives of living genera. Anaplecta vega sp.n. –the second described cockroach from Miocene (23 Ma) Simojovel amber (Mexico: Chiapas: Los Pocitos) is characterized by a slender, under 5 mm long body, prolonged mouthparts bearing long maxillary palps with a distinct flattened triangular terminal palpomere, large eyes and long slender legs with distinctly long tibial spines. Some leg and palpal segments differ in dimensions on the left and right sides of the body, indicating (sum of length of left maxillary palpomeres 65% longer than right; right cercus 13% longer than left cercus) dextro-sinistral asymmetry. The asymmetrically monstrous left palp is unique and has no equivalent. In concordance with most Cenozoic species, the present cockroach does not show any significantly primitive characters such as a transverse pronotum characteristic for stem Ectobiidae. The genus is cosmopolitan and 10 species live also in Mexico, including Chiapas, today. Except for indigenous taxa and those characteristic for America, this is the first Cenozoic American cockroach taxon representing a living cosmopolitan genus, in contrast with representaties of Supella Shelford, 1911 from the same amber source that are now extinct in the Americas.

Anaplecta is a cockroach genus currently placed within Ectobiidae, a family that evolved during the Mesozoic (Vršanský, 1997). Species in the subfamily Anaplectinae are small, beetle-like and mostly active during the night (Rentz, 2014). Both sexes are fully winged and can be found in the leaf litter of rainforests (Foottit & Adler, 2009).
The specimens Anaplecta xanthopeltis Hebard, 1921(MNHN-EP-EP1398, 2018 and Anaplecta maronensis Hebard, 1921(MNHN-EP-EP1385, 2018, used for comparison with living Anaplecta, are deposited at the National Museum of Natural History in Paris, France. Photographs were taken with a KEYENCE digital microscope, which took pictures from different locations and focal depth and then automatically combined them into a single stacked photo. This type of picture was also used as a basis for making a highly detailed line drawing in CorelDrawX3, where we used additional photographs of separate parts of the cockroach body. These were taken with a LEICA MZ6 binocular loupe and LEICA EC3 camera. The dorsal drawing was manually made using a drawing ink pen applied over a transparent paper. Abbreviations used: l, length; w, width (all in mm). The electronic version of this article in Portable Document Format (PDF) will represent a published work according to the International Commission on Zoological Nomenclature (ICZN), and hence the new names contained in the electronic version are effectively published under that Code from the electronic edition alone. This published work and the nomenclatural acts it contains have been registered in ZooBank, the online registration system for the ICZN. The ZooBank LSIDs (Life Science Identifiers) can be resolved and the associated information viewed through any standard web browser by appending the LSID to the prefix http://zoobank.org/. The LSID for this publication is: [article: urn:lsid:zoobank.org:pub:FD6F76DB-BF88-4FBA-8737-F00B408C54E1]. The online version of this work is archived and available from the following digital repositories: PeerJ, PubMed Central and CLOCKSS. Composition. An up-to date list can be found in the online database 'Cockroach Species File Online', which was founded by Beccaloni (2014) based on the world catalogue of cockroaches compiled by Princis (1962;1963;1964;1965;1966;1967;1969;1971  Etymology. After VEGA (Vedecká Grantová Agentúra -Research grant agency of the Slovak Republic) and also after Dr. Francisco Vega (UNAM, Mexico city) who did so much for progressing research on Chiapas amber. Differential diagnosis. Small slender roach with body l = 4.89 (excluding antennae and cerci) and w = 2.00; subtriangular rounded pronotum; prolonged head with unique large eyes and huge asymmetrical maxillary palps; antennae similar in length as the body; tegmina reaching apex of abdomen; long slender legs bearing long tibial spines.

SYSTEMATIC PALAEONTOLOGY
Differs from all species, except for A. xanthopeltis, in having a derived simplified form of the pronotum (without paranotalia and transverse shape) and, except for A. maronensis, a derived reticulated forewing venation.
Differs from recent species from Mexico (since this genus contains a large number of species worldwide and no other fossil species of this genus were described from this area): A. azteca (Saussure, 1868) is larger, its pronotum is double the length and width of the pronotum of A. vega, the pronotum length is 1/3 of tegmina length, while in A. vega it is 1/4.
A. fallax Saussure, 1862 has quite a similar tegmina length and total body length, but the pronotum is distinctly larger, can reach almost two times the dimension of the pronotum of A. vega; the pronotum length can be more than 1/3 or even 1/2 of the tegmina length. Anterior margin ascending under sharper angle from the distal third of tegmen length forming a rounded angle, while in A. vega it is at the beginning of the most distal fifth of the tegmen length.
A. mexicana Saussure, 1868; while having a similar tegmina length and pronotum length ratio, the whole body is significantly larger and the tegmina length is double the tegmina length of A. vega. The shape of tegmina differs with the anterior margin slightly sinusoid without any pronounced angulation, the tegmina apex is more broadly rounded and positioned around the middle of the tegmen width. A. nahua Saussure, 1868 is larger, the tegmina length: pronotum length ratio is quite similar to that of A. vega.
A. otomia Saussure, 1869 is larger, dark colored, pronotum with nearly opaque lateral margins, tegmina in apical third strongly narrowed unlike A. vega. Its anterior margin does not look angular in the apical fifth and is curved smoothly, and the radius area of the tegmina is much narrower.
A. saussurei Hebard, 1921 has a similar size and similar shaped tegmina as A. vega, but the tegmina reach slightly beyond the cercal apices, are slightly wider, their anterior margin in the basal part is almost straight, the clavus is distinctly longer and wider, the pronotum is larger and the pronotum length is 1/3 of the tegmina length.
A. tolteca Saussure, 1868 is larger but the tegmina length: pronotum length ratio is the same as in A. vega.
A comparison of dimensions of A. vega n. sp. and the above mentioned Mexican species is presented in Table 2A; a comparison of A. vega n. sp. dimensions and an average of the mentioned Mexican species dimensions is shown in Table 2C. Description. Detailed measurements are in the Table 2. Body small and slender (l = 4.89, w = 2.00), tegmina reaching apex of abdomen, legs long and slender carrying large tibial spines, antennae similar in length to the body. Pronotum subtriangular, rounded, cranially arched over head (l = 1.00, w = 1.27), long erect setae sparsely distributed along pronotum margin and on its dorsal surface. Pronotum length is 1/4 of tegmina length. Scutellum triangular, cranio-caudally prolonged (length of scutellum part not covered by pronotum = 0.29, w = 0.14). Tegmina total l = 4.04, l of part not covered by pronotum = 3.89, left tegmen w = 1.28; visible left clavus l = 1.16, w = 0.67. Basal half of tegmina inflated with exception of anterior peripheral areas (costal area, part of radial area). Anterior margin in the apical fifth of tegmen length starts to tilt posteriad more strongly, which gives it an angular look. Apex postero-apically sharpened. Costal area wide. Radial field in apical half wide,    Table 2B. Labial palps considerably smaller than maxillary palps, terminal palpomere triangular, distally widened. Only 2nd and 3rd left labial palpomere sufficiently visible to be measured: 2nd left palpomere l = 0.11, 3rd left labial palpomere l = 1.13. Antennae length similar to body length. First three antennomeres only with few setae, more distal antennomeres are richly covered by distinct setae, which exceed and in some parts double the width of antennomeres. Scape large (left l = 0.33; right l = 0.29) with wide proximal half (left w = 0.13) and sharp transition into narrower distal half (w = 0.09), distal ending oblique with five setae.
Pedicel cylindrical (left l = 0.21, left w = 0.08; right l = 0.2), distal end oblique with distinct sharp angle at one side and wider than proximal end. Proximal third swollen on one side. Setae very few in number.
Segments of flagellum, 32 in left antenna, 28 in right antenna. Each segment is more or less wider in its distal part than in its proximal part. Setae longer than the width of flagellar segments.
First flagellar segment (third antenomere) slightly elongated, length is almost two times as its largest width (left l = 0.14, w = 0.07). Following basal flagellomeres are short almost square shaped flagellomeres only slightly longer than wide. The subsequent row of flagellomeres has a lengthening trend distad. Table 2E shows a chart that compares left and right antennomeres lengths of individuals.
Cerci 7-segmented. 1st cercomere and 7th cercomere thinner than the rest, while the 7th distinctly tapers distally forming a sharp end, cercomeres 2-6 sublenticullar, being similar in shape and size. Left cercus total l = 1.00, right cercus total l = 1.13; Setae on cercomeres have different dimensions, from small ones ranging from 1/3 or 1/4 of the cercomere length to thicker prominent setae approximately the size of the cercomere length (maximal l = 0.21, but majority around 0.14) and long thin setae the size of two or three cercomeres which occur at the rate of 1 or 2 per cercomere. The entire surface of the cerci is also covered by very small short microsetae. Legs slender and very long (hind legs longer than body) with large spines (longer than tarsomeres, except the 1st tarsomere) on tibia and distal end of femur. Fore coxae subtrigonal with convex anterior margin, widest before middle , more slender in distal half. Few setae present along the posterior margin. Fore trochanteri very thin, barely visible. Fore femora slender (left fore femur l = 1. 29, w = 0.2, right fore femur l = 0.67, maybe more, visibility obscured by damage of amber) with subparallel ventral and dorsal margins, which are only slightly convex, narrower in proximal part and in distal third of their length. Anteroventral margin in distal half with 20 ± shorter spines, posteroventral margin with 13 (observed) longer setae sparsely distributed along fore femur length, two thicker spines present on anterior surface of proximal half of fore femur. Terminally three long serrated spines present: anteroventral, posteroventral, anterodorsal. Rest of forefemoral surface covered only by a low number of shorter setae, mostly concentrated in dorsal part. Fore tibiae distinctly more slender than fore femora, generally retaining similar width (w = 0.07) throughout its length (left fore tibia l = 0.89, right fore tibia l = 0.73), except for the thinner arched proximalmost spineless part (w = 0.06), and neglectable changes of width due to elevations around large, articulated, serrated spines; these spines are up to 0.29 long and 0.01 wide with three spines in the middle third of the tibial length and two peripheral spines facing dorsad, the middle one facing posteriad. Four large spines are at the distal end of the tibia (1 anteroventral, 1 anterior, 1 dorsal, 1 posterior). Distribution of large spines is the same on both right and left fore tibiae. Along dorsal and ventral side and distal half of anterior surface are sparsely distributed medium-sized setae. Fore tarsi being 5-segmented, very slender, covered by setae exceeding their width (w = 0.04), terminated by trilobal arolium and two thin arcuate, more or less symmetrical claws with widened bases. Middle coxae (distal part obscured by damage in amber and another leg) larger and wider than fore coxae, on posterior margin few setae present; distal end has distinct smaller lobe with 6 longer setae. Middle trochanteri wide (width is only a little less than length), slightly curved. Middle femora elongated with slightly convex dorsal and ventral side (ventral side being almost straight) with bigger width around the middle of length (left middle femur l = 1.44, w = 0.22 mm; right middle femur l = 0.91, w = 0.17). Setae sparsely distributed around dorsal margin, ventral margin with 6 larger thick setae and 1-2 medium-sized setae between each two consequent larger setae; on proximal half of middle femur present anteroventrally two longer, anterad facing spines; on distal end of middle femur present 3 large serrated spines, one anteroventrally, one posteroventrally and one dorsally. Middle tibiae similar in length (left tibia l = 1.16, right tibia = 1.11), but left tibia 1/6 shorter than left middle femur, right tibia 1/5 longer than right middle femur; width varying along tibial length as result of elevations at the bases of spines (minimum w = 0.07, maximum w = 0.1); 10 large serrated spines (maximal l = 0.36, w = 0.01) facing differently (on left middle tibia 1 anteroventral, 1 posteroventral, 4 anterodorsal 4 posterodorsal) along tibial length, 4 terminal large serrated spines (anteroventral, posteroventral, posterodorsal, anterodorsal) and one shorter spine (posteroventral). Middle tarsi 5-segmented, slender, covered by medium sized setae exceeding tarsal width (w = 0.04 mm), terminated by two arched slender claws with widened bases and trilobal arolium. Hind coxae badly visible. Hind trochanteri slender, slightly curved with few setae, left hind trochanter l = 0.43, w = 0.11; right hind trochanter l = 0.46, w = 0.09. Hind femora larger than fore and mid femur (l = 1.4, w of right hind femur = 0.31, left one in wrong position to be measured) with biggest width in the middle of their length, distal end slightly widened, ventral side only slightly convex, dorsal side more convex. Numerous short setae scattered through whole surface of femur. Setae sized from short to long present along dorsal femoral margin, getting longer distad; at anterior surface setae with dark bases present at an arched line subparallel to the dorsal side of femur, which proximally starts around the middle of hind femur width, approaching dorsal side of hind femur distad. Dorsal and anterior setae are longer on left fore femur. Anteroventral edge with medium-sized setae and two large spines in the middle third of hind femur length. Posteroventral edge with five long setae (left hind femur) and shorter setae between them. Terminally three long serrated spines present: anteroventral, posteroventral, anterodorsal. Hind tibiae longer than fore and mid tibiae (left hind tibia l = 1.89, right hind tibia l = 2.13) near double length of middle tibiae, width of hind tibiae is weakly varying due to elevations at bases of larger spines, but not showing a significant narrowing or widening trend (maximal w = 0.13), exception is the proximal 1/6 which is more slender (w = 0.1 mm). Each hind tibia has along its length 17 long serrated spines (three anteroventral, two posteroventral, seven anterodorsal, five posterodorsal) and five long serrated terminal spines (1 anteroventral, two posteroventral, one posterodorsal, 1 anterodorsal), which makes together 22 spines on one hind tibia (maximal spine l = 0.5 mm maximal w = 0.02). Medium sized seatae are sparsely distributed along ventral and dorsal margin (up to 4 between two spines). Hind tarsi larger than fore and mid tarsi, 5-segmented, slender, covered by medium sized setae most of which equal in size or exceeding tarsal width (w = 0.06), terminated by two arched slender claws with widened bases and trilobal arolium (pulvilli absent or indistinct). 1st tarsomere very longwith almost same width throughout its length, in proximal part slightly thinner; covered by distinct medium sized setae, most prominent is the ventral row of setae, other areas have less densely distributed thinner setae; subsequent tarsomeres have the same length on left and right hind leg.
Comparison of length of each leg femora, tibiae and tarsomeres is visible in Table 2D. Occurrence. Lower Miocene, 23 Ma. Chiapas amber, Mexico.

DISCUSSION
The assignment of the herein described specimen to the subfamily Anaplectinae is in accordance with Grandcolas (1996). The majority of autapomorphies listed there are observable also in A. vega. It is in general small-sized species, other small-sized dictyopterans were observed and discribed in Vršanský (2002). Long, straight setae on pronotum, strong sharp apophysis on the anterior arch and transverse folding of hind wings are present. However, the vannus with short successive dichotomies on its first vein was not observed. The studied specimen was assigned to the genus Anaplecta on the basis of the overall body shape, shape of the pronotum, smooth dorsal half of the body, large axe-like terminal mandibular palpomere (however, it does not have the same length as the former palpomere, as mentioned in the original description of the genus), coriaceous tegmina, hind wings folded in half, arrangement of femoral setae and spines, large cerci, and tarsomeres without pulvilli. The specimen is most similar to and compared with the holotypes of South American A. xanthopeltis Hebard, 1921 andA. maronensis Hebard, 1921, which have the same type of pronotum, overall tegmina shape, tegmina type of venation and hind wings folding. Anaplectinae is usually considered a problematic group with an interesting systematic background. It is manifested both in morphological and molecular analysis as a ''long branch'', the most basal, earliest derived group among extant standard cockroaches according to the molecular analyses (Klass & Meier, 2006;Legendre et al., 2015). In contrast, the fossil record reveals earlier branched Ectobiidae and Blattidae (Sendi & Azar, 2017) and Anaplecta is considered more recent.
It is an interesting fact, that the evolution of this group is accelerated, which is not only reflected in sclerotisation of the fore wing, but also in simplification of venation, which probably happened due to miniaturization of the body. The large asymmetry in leg dimensions on the left and right sides of the body (Table 2D) and distinctly larger left maxillary palpomere (Table 2B) are also evidence of nonstandard evolution of the genus Anaplecta.'' The coriaceous tegmina are not sclerotized completely enough to be considered as elytrised, which is also seen in living A. maronensis.
In respective descriptions of living Mexican species the data about the ecology of Anaplecta are missing. The diversity of the genus is very high in rainforest areas. Evangelista et al. (2015) highlight four species in Amazonas (Venezuela), four species in Guyana, 10 species in Suriname, nine species in French Guiana, 10 species in Ampa (Brazil); Vidlička (2013) mentions 10 species in Ecuador; eight species (including the new species) are known from Mexico based on the works of Saussure (1862), Saussure (1868), Saussure (1869) andHebard (1921).
The genus Anaplecta has presently a circumtropical distribution, and the (sub)tropical climate supports the newly described species as well. Fossil Anaplecta species are also known from Eocene Baltic Kaliningrad and Chinese ambers-the climate during Eocene in these areas was subtropical (Grimaldi, 1996), and from the related Dominican amber (nevertheless, the Dominican species are undescribed and taxonomical placement needs confirmation-see above).
The palaeogeographical inferences are principal, as it has been shown that the Eocene North American fauna (major locality Green River, Colorado, U.S.A. but also more northern localities in Canada-Greenwood et al., 2005, Archibald & Mathewes, 2000 and also the Miocene fauna of Chiapas amber was cosmopolitan, while younger Dominican amber contains modern, American cockroach taxa-strongly suggesting a major extinction between these two time periods (of deposition of these two sites- Vršanský et al., 2011). The present study cannot reveal information on whether Anaplecta, inhabiting Americas today, is a native trace of the original Eocene diversity or a descendant of a more recent re-invasion. This research awaits future investigation.
The detailed phylogenetic study of Djernaes, Klass, & Eggleton (2014) and Vidlička et al. (2017) positioned the Anaplectidae into one clade together with Tryonicidae, Cryptocercidae and Isoptera based on what seems to be a very primitive taxon. However, according to our morphological and taphonomical (i.e., absence in the rich Mesozoic record counting 30,000 sedimentary and over 3,000 amber specimens) observations, Anaplecta is a modern (plesiomorphy such as non-fully elytrised tegmina of the present species are also shared with some living representatives-see above) and developed genus typical of the Cenozoic.
The asymmetry of genitalia is common and appeared repeatedly during the insect evolution (Huber, Sinclair, & Schmitt , 2007), it is even part of the original ground plan in the whole order Dictyoptera. Asymmetries in left-right axis of other body parts can be also found among insects (Smith, Crespi, & Bookstein , 1997). The fluctuating asymmetry can predict developmental instability of the individual (Dongen, 2006). In that case, the studied individual was vital and the unevenness of certain body parts did not affect the fitness or if it did, not fatally. The difference between left and right hind legs is neglectable (Femur (F) = 1.014[r]/ Tibia (T) = 1.12[r]/ Tarsomere (Ta) 1 = 1.08[l]/ Ta2 = 1/Ta3 = 1/Ta4 = 1/Ta5 = 1). It explains the importance of the hind leg in the movement (Hughes, 1952). In contrast, the front femur leg (also important in the movement) is highly asymmetrical. The biggest difference can be found between the left and right femur (the left femur is almost twice as big). Also, the overall asymmetry is more evident (F = 1. The expansion of extremities longitudinally could have been caused post mortem, by tension of polymerizing resin. The structure of resin can be modified due to conditions such as temperature, humidity change, etc. These changes can affect the state of preservation of the inclusion (Poinar Jr & Mastalerz, 2000).
The irregularity in length of extremities could have also happened while attempting to escape after being embedded in resin, which often even leads to disarticulation (Martínez-Delclòs, Briggs, & Peñalver , 2004).

CONCLUSIONS
The Miocene cockroach Anaplecta vega sp.n. represents an extinct species of an extant genus and is consistent with a cosmopolitan pattern of Cenozoic occurrences. Its closest relatives live in South America, with which it shares the pronotum shape, tegmina shape and venation, and hind wing folding. Since the living representatives of Anaplecta prefer warm climates, Anaplecta vega probably also lived in warm (sub)tropical areas. It is the second cockroach species described from Chiapas amber, Mexico and belongs to the subfamily Anaplectinae, family Ectobiidae. The described individual shows noticeable asymmetries in maxillary palpomeres length, right cercus and some leg segments. The asymmetry regarding the genotypic or phenotypic origin remains obscure and needs further study.

ADDITIONAL INFORMATION AND DECLARATIONS Funding
This work was supported by the Slovak Research and Development Agency under the contract No. APVV-0436-12 and by UNESCO-Amba (MVTS); VEGA No. 0012-14, 2/0042/18. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.