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AutorCorrespondencia: apretana@gmail.com*
Revisionary paper
Characters in Thysanoptera
AXEL P. RETANA-SALAZAR* Programa Universitario de Biologa Aplicada (PUA), Centro de Investigacin en Estructuras Microscpicas(CIEMic), Ciudad de la Investigacin, Universidad de Costa Rica, 2060.
R ESUMEN : Thysanoptera es un grupo de alta homoplasia como ha sido establecido en la literatura pormltiples autores. Esto ha tenido un efecto en la discusin entre los taxnomos que invierten grandescantidades de tiempo en la discusin de la validez de los caracteres utilizados en este grupo de insectos. Esto
se refleja en mltiples trabajos de taxonoma en los que se describen especies y grupos sin unafundamentacin filogentica. De igual forma decisiones tomadas en funcin de resultados filogenticos sonmuchas veces cuestionados ya que los mismos van en contra de una clasificacin ms cmoda. En estetrabajo se presenta una revisin corta de las tendencias y problemas en los diferentes tipos de caracteres quese utilizan en Thysanoptera en la actualidad y la necesidad de tener mayor cuidado con el trato de algunosde estos caracteres en la toma de decisiones taxonmicas, en las cuales se proponen cambios en laclasificacin biolgica.
PALABRAS CLAVE : Filogenia, caracteres moleculares, caracteres morfolgicos, caracteres biolgicos,caracteres teratolgicos, cladstica., Thysanoptera, Thripidae.
ABSTRACT : Thysanoptera is a group of high homoplasy as has been established in the literature by many
authors. This has had an effect on the debate among taxonomists investing large amounts of time discussingthe validity of the characters used in this group of insects. This is reflected in many taxonomic works,described species and phylogenetic groups without a foundation. Similarly decisions based on phylogeneticresults are often questioned since they go against a more comfortable classification. This paper presents ashort review of trends and issues in different types of characters used in Thysanoptera today and the needfor a more careful treatment of some of these characters in taxonomic decisions in which changes in the
biological classification are proposed.
K EY WORDS : Phylogeny, molecular characters, morphological characters, biological characters, teratologicalcharacters, cladistics., Thysanoptera, Thripidae.
I NTRODUCTION
Thysanoptera is a complex group especially because of its high level of homoplasy (Gauld &Mound 1982, Mound & Palmer 1983, Retana-Salazar 1998, 2000). However it is one of thegroups with fewer amounts of formal
phylogenetic analysis and with a very common practice of -taxonomy of the specialists that
are more occupied in the description of new
species than in the determination of the naturalgroups.
The recognized authorities focused in the -taxonomy producing several hundreds of pages
per year full of subjective criteria about theimportance of the characters used by eachauthor. This practice was abandoned in the
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majority of the groups, where several authoritiesdont consider the publication of speciesdescription in absence of good phylogeneticanalysis and revisionary works as good exercise(Retana-Salazar 1998, 2000, 2006, Retana-Salazar & Ramrez Morales 2006).
Before the last 20 years only Johansen inseveral papers (Johansen 1982, Johansen1983a,b, 1986a,b) approached the topic of theuse of characters to rigorous analysis that showits validity in taxonomic decisions. Some otherworks have been strongest criticised for thechoice of the characters related with no correctthe hierarchical level or for the publication ofsome obscure cladistic results (Bhatti 1993).
In several groups the comparative study of thecharacters in species that are close together isnecessary to establish the possible change of thestates of characters, but that is not enough forthe determination of the evolutionarydevelopment of each character (Wiley 1981,Retana-Salazar 2006).
In the last years, important papers aboutmolecular data in Thysanoptera have appeared.One of the most important is the publication ofMorris and Mound (2005). Other researchersused morphological features as principalcharacters, but the use of morphologicalcharacters may be dangerous if the importanceof the character is not correctly evaluated asgood characters in phylogenetic resolution(Bjrklund 1997, Diniz Filho 2000, Retana-Salazar & Retana-Salazar 2008). In these casesthe subjective consideration of the possibleevolutionary origin of the characters is adangerous practice that shows the a priori ideasof the taxonomist more than the realevolutionary change.
SYSTEMATIC PHYLOGENETICS IN THYSANOPTERA
Mound and collaborators (1980) presented a phylogenetic paper concerning the familyclassification in Thysanoptera. This work hassome methodological problems that prevent therepetition of these results, especially the absenceof the type of analysis formally used, i.e. somedetails like the selected software, the
polarization criterion of characters, the analysisof homoplasius and homologue characters, thestatistics of the trees obtained and the supportindex, among other things. For this reason theworks of Johansen (1982, 1986a,b) areconsidered the first formal phylogeneticanalysis. Excellent revisionary work was
performed by this author on the taxonomy, biogeography and phylogeny of Elaphrothrips , Leptothrips and Humboldthripini. In the first paper about Humboldthripini this authorincludes all the tribes of Thripinae.
Johansen is clear in the description of charactersand the detail of the methodology used for the
phylogenetic reconstruction. This technique isthe only weakness of this analytical work,
because it does not include the use of specificsoftware nor the analytical study of characters,
but presents a good statistical approach to thedistribution of characters that permits therepetition of these results. However thedescription of characters is the most important,with extensive character states all well-defined.That is the real strength of this work andcharacter definition is the most important step ina good phylogenetic analysis.
The work performed by Mound andcollaborators (1980) as a phylogenetic analysiswith absence of all the necessary technicalconsiderations, which are indispensable forothers that wish to try and reproduce thoseresults, is an example of some critical papersthat need extensive revision on the phylogeneticresults performed. Several times I have tried toutilize this data matrix with different softwarefor phylogenetic reconstruction but I havent
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been successful in obtaining the same results asthese authors (Figs 1-3). The only alternative inobtaining these results is using constraints forthe topologies depicted (Figs. 4, 5). This impliesthat these results are not in the set of optimalsolutions and is a particular restriction for a
particular result. It is relevant to note that theresults obtained without the use of constraintsshow better statistical fit (Figs. 1-3). Theseresults indicate that the considerations of Bhatti(1993) seem to be correct when he commentsabout this work : The changes they prop osed inthe family classification of Terebrantia did notarise from cladistic analysis. They did notreconstruct the phylogeny. They merely plottedthe character states on two proposedcladograms(page 99). A similar problem isevidenced when analyzing the data matrix usedfor the study of the phylogenetic relationshipsamong groups of Aeolothripidae (Marullo &Mound 1995)(Figs. 6, 7).
Recent works from Morris and collaborators(1999) have several methodological problemswidely discussed in phylogenetic papers. Theseauthors use very small numbers of charactersconsidering the number of taxa included. Thecharacters considered are not the best at ageneric and supraspecific level. Severalconclusions are not well founded in these resultsand they considered this phylogenetic analysisas definitive in order to propose patterns ofevolution.
The works of Retana-Salazar (1998, 2000, 2001,2006, 2007a,b, 2010) are classical cladisticwork, using new alternatives in the phylogeneticreconstruction, particularly useful in highhomoplasius groups, where the common use of
parsimony may conduce to unreal results(Brooks & Wiley 1986, Retana-Salazar &Retana-Salazar 2008). All propose newhypothesis and as such are subject to proof. Asrequired by formal science. Recently Cavallieriand Mound argued that As in all branches of
science, conclusions in taxonomy can be nomore reliable than the data on which they are
based (Cavallieri & Mound 2012, page 1).However, in many of Mounds articlesconcerning aspects of the phylogeny ofThysanoptera, there is a lack of reliability in themethod.
These papers are an effort in the search ofobjective tools for the determination of thecharacters that show natural groups inThysanoptera (Retana-Salazar & Retana-Salazar2008). Based in his results this authordemonstrates the necessity to use phylogeneticanalysis to define the possible directionality ofevolutionary changes and the necessity tosegregate some genera into several ones butdefining the natural groups using phylogeneticanalysis (Retana-Salazar 2006, Retana-Salazar& Soto-Rodrguez 2007, Retana-Salazar &
Nishida 2007).
CLADISTICS AS A TOOL FOR TAXA DESCRIPTION
The philosophy of cladistics suggests thenecessity to take some axiomatic purposes forthe correct reconstruction of phylogeny.
Some particular groups as Frankliniella , Thrips , Hoplothrips , Elaphrothrips, Heterothrips andothers, have a great number of species and thehomoplasious level is high, commonobservation is not enough to define whichcharacters are homologues or homoplasious.The use of a data matrix of these characters toobtain a hypothetical tree permits the
phylogenetic study of the characters behaviourand its phylogenetic value.
Choosing a correct out-group may be difficultwhen the in-group is highly homoplasious. Thechoice of an incorrect out-group can lead toequivocal and not congruent relationships. Isuggest two practices for this delicate scenario:a) the use of several out-groups all of them with
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characters shared with the in-group (Retana-Salazar 2010), or 2) the use of a hypotheticalancestor created using characters observed inseveral other taxa (Retana-Salazar 2007a). Inthis aspect Mound and collaborators (1980) andBhatti (1988, 1993) suggest possible data for theinference of the hypothetical ancestor. The useof multiple out-groups can be very useful ingroups with few species where the diagnosticcharacters are well defined (Retana-Salazar2007a). By contrast, in taxonomic groups wherethere is no clarity on the limits of the taxa andthere is no homogeneity of the characters usedin grouping, the use of multiple out-groups maynot be of much help except to determine the
paraphyly of the ingroup (Retana-Salazar 2010).
BIOLOGICAL CHARACTERS IN THYSANOPTERA
Some authors suggest (Mound & Marullo 1996)that the uses of these criteria are in several cases
better than the morphological inference, becausethe plasticity of morphological features maylead us to mistaken associations. Lamentablythese characters are diagnostic in few cases.One relevant case where biology has been themost important feature is Aulacothrips recognized as family level by Bhatti (2006) it iswell supported by morphology, biology and
biogeographic features. In this particularspecies, the only one known to be anectoparasite of insects and whos natural hostsare the individuals of Aetalion , and somemembracids is one extreme case and there is nodiscussion about this. Other groups are not soclear in those biological features (Alves-Silva &Del Klaro 2011).
Several species of Frankliniella are closelyrelated to Asteracea species, and only one isstrictly associated with Hemerocallis , while feware strictly associated with mosses (Mojica &Johansen 1990, Mound & Marullo 1996,Retana-Salazar 1998), but it is difficult toestablish that these particular groups are
different taxa only based on their biology.Retana-Salazar (2010) shows that these
biological features are only significant for thecharacterization of species, but not for groups ofspecies.
Biology may be highly homoplasious because biological features are very plastic, and in thesecases the uses of biological features in absenceof other morphological characters is not a goodindex for group segregation.
MORPHOLOGICAL CHARACTERS AND THEPROBLEM WITH SPECIES RECOGNITION
The morphological characters may be veryvariable, but we need critical studies of thegroup variation for making good taxonomicdecisions. Bhatti (2006) established thattaxonomy as we know it is reallymorphotaxonomy, because we need particularmorphological features for the description andcomparison between species.
Some particular features as the brachipterouscondition of some species in Frankliniella andThrips may lead to the recognition of naturalgroups with a particular morphological feature(possibly apomorphic character) that defines thegroup. This consideration without a formalanalysis of other characters may bring us toincorrect phylogentical assumptions.
In the genus Thrips it seems that this characteris associated with other derived characters andthe brachipterous species may form a realnatural group. In Frankliniella the situation isvery different and the brachipterous forms arenot supported by other derived characters andthe reduction of the wings seems to appearseveral times in the evolutionary history of thegroup (Retana-Salazar 2010).
The number of antennal segments is analyzed by Mound and Palmer (1981) in six genus-
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groups in Thripina. This author suggested thatthe plesiotypic condition is 9 segments, somegroups in Aptinothripina and all the genera inPseudothripini seem to have a secondarydevelopment of this 9-segmented condition.Mound and Palmer (1981) suppose that thiscondition derives from the subdivision of thesixth segment. With this evidence Mound andPalmer (1981) suggest that the most commonapomorphic condition is seven antennalsegments. This consideration leads to the
possibility of interpreting the presence of six,seven and eight as an apomorphic sequence.
Recent studies in the genus-group Anaphothrips (Retana-Salazar 2007b, Retana-Salazar 2010)demonstrate that these conditions may bereversal on several occasions. They are useful inthe diagnosis of genera, the studies in the
Anaphothrips group evidenced that thistransformation has good phylogenetic inertiawith the hierarchical level of genus. A similarcondition is presented by the phylogeneticanalysis of the Hoodothrips genus-group(Retana-Salazar 2007a). In this particular casethe fusion of segments may occur not only inthe terminal segments. This feature complicatesthings when considering apomorphic and
plesiomorphic conditions. Those are goodexamples of how the same characters, in generathat seem phylogenetically close, or at leastincluded in the same family, have a verydifferent evolutionary landscape.
Mound and Palmer (1981) proposed the uses of8 morphological characters for the segregationof genus-groups in Thripina. These authors
proposed a particular polarity from thesecharacters based on merely observational dataof slides. This methodology suggested that theanalysis may be erroneous; Retana-Salazar(2008) uses a data matrix with these 8characters in the phylogenetic reconstruction ofthe relationships of the genus-groups proposed
by Mound and Palmer (1981). In this paper
Retana-Salazar (2008) considered thosecharacters under a formal analysis and use forthe determination of polarity recently describedfossil form with a good number of specimensthat permit a good observation of the major partof characters (Pealver 1998). Results of thisanalysis show that the values of these charactersin genus-groups definition are very poor and themajority is not well associated with the
phylogenetic structure of these groups. Thiskind of work reveals that considerations about
polarity of characters in absence of formalanalysis of phylogeny and based only inobservation of the alpha taxonomists, may leadto grave mistakes that may be reflected inerroneous taxonomic decisions.
For this reason we need to 1) establish a phylogenetic hypothesis and 2) decide based onthese results which characters have a good
phylogenetic fit in each case and then these will be the features used in the definition of naturalgroups. This fit needs to be measured usingsome important tools, like the measure of the
phylogenetic inertia of characters (Bjrklund1997, Diniz-Filho 2000, Retana-Salazar &Retana-Salazar 2008) and the evaluation of theless entropic topology for a same data matrix(Brooks & Wiley 1986, Retana-Salazar 2007a,Retana-Salazar & Retana-Salazar 2008).
In Tubulifera the problem is the same. Moundand Marullo (1996) proposed that in the
Liothrips lineage, the presence of one sensoriumin antennal segment III and three sensoria inantennal segment IV are characteristics of thisgeneric group. The phylogenetic analysis
performed by Morris and collaborators (1999)using morphological features shows that thiscondition in antennal segments III-IV came upseveral times in the evolutionary history of thegroup. These characters have a low
phylogenetic inertia and for this reason are notgood in defining the lineage.
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However this kind of characters is good for thesegregation of generic taxa, particularly thenumber of antennal sensoria in antennalsegment IV in the Karnyothrips lineage(Retana-Salazar & Soto-Rodrguez 2007).Recently Minaei and collaborators (2007)redefined the genus Noeheegeria , and in this
paper, without any particular phylogeneticarrangement the authors considered that thisfeature (antennal sensoria), is indeed valid forthe segregation of genera. These authorsanalyzed the presence of this feature in a groupof species that shows this particular character,
but its presence is not enough for separating ifwe do not know whether these characters are
plesiotypic or apotypic, because apormorphouscharacters could support all segregation. This
biological problem to define which charactersare apomorphous and which of them are
plesiotypic, as well as the determination ofhomoplasius characters, is only resolved by
phylogenetic analysis.
These problems with morphological charactersare biological hurdles usually appointed inliterature. Moreover, there are other kinds of
problems with morphology in Thysanoptera.The preparation procedure can affectmorphology. For example, Hoyers mediumcreates undulating setae and produce distortionof the colour and the original shape of thespecimen. This is due to it not being viscous atall and the cover slide then stretches the sample,destroying the original shape of the specimen.The macerating substance affects coloration andthe clarity with which some characters areobserved. Excess pressure on the cover slidestretches the sample producing distortion of themorphological features, for example widerabdomen and head bases, together with longermouth parts and displaced and longer setae(Retana-Salazar & Mound 1994).
Retana-Salazar & Mound (1994) proposed thatvariation within a species can be greater than
variation among several species, but thisaffirmation needs further studies because highlyvariables species such as Fr. occidentalis and
Fr. intonsa may be a species complex. Mound(2005) suggests that phenotypic plasticity is agreat source of morphological variation withinspecies, but this asseveration needs severalcontrolled experiments to prove it and not justthe personal guess of a taxonomist.
MORPHOLOGICAL TRAITS OF THE IMMATURESTAGE
The characters of the immature stages could beuseful determining the species as in the case of
Selenothrips rubrocinctus where the speciesname refers to the main feature of the larva II,the presence of a red band at the middle of
body. In other cases, such as Taeniothripsinconsequens where has been reported the
presence of a well-developed toothed comb inthe terminal segments of the abdomen of thelarva II, which is characteristic of the species(Lacasa and Llorens 1996)(Fig. 8). The
presence of distinctive characters in somespecies has caused to put aside the integral
description of the larva II, thereby losing a largeamount of information that can be of value instudies of phylogeny.
The characters of the immature can be useful in phylogeny and taxonomy, making it necessaryto develop studies of the ontogeny of thecharacters, as has been done in groups likeCulicidae (Harbach 1991). In Thysanopterahave been studied little morphologicalcharacters of the different stages of
development. There is no clear characterizationof the genera at the immature level but if thereis numerous descriptions of the larvae of somespecies of thrips. A first step in systematicresearch into the characters of larval forms inThysanoptera is to determine the generalfeatures that define the different genera andtaxonomical value of these characters.
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An interesting example is the study of theimmature of Frankliniella insularis where theadult female is characterized by the absence ofmedial comb on the posterior margin of sternumVIII (Fig. 9a), among other features, but theobservation of larvae II shows that this comb isnot present in abdominal segment VIII but asimilar but small and complete similar structureis in abdominal tergum IX in this stage (Fig.9b). This can be useful in the polarization of thischaracter.
The structure of the segments of the antenna can be a good Terebrantia taxonomic character. InThripidae segments III-IV of immatures are
very developed and segments V-VII are forminga stylus (Fig. 10a, b). In Aeolothripidae antennalsegments are evident since very early as welldeveloped units of similar structure to that ofadults but with fewer segments (Fig. 11a). Inaddition, in Aeolothrips intermedius hasascertained the presence of a double comb in thecaudal segments of the abdomen (Fig. 11b),while in adults there is no evidence of suchstructures.
Preliminary data has given rise to start at theUniversity of Costa Rica a project to describesystematically the characters of the larvae of the
principal species of thrips. These data will beginstudies on the importance of ontogeny in
phylogenetic characters polarization.
TERATOLOGICAL CHARACTERS
These characters are abnormalities recorded bytaxonomists after the revision of a long series of
individuals. Such variation is highly diverse, inmost animals it may be identified because theindividuals involved either deviate markedlyfrom type as to be recognized as freaks or
because the abnormalities involved areasymmetrical (Mayr 1969). Teratologicalcharacters may not be used in taxonomicdecisions, however recently Goldarazena and
collaborators (2008), used a particular characterin a few individuals to synonymize a recentlydescribed species. This type of mistake may bedangerous because some journals publish theseequivocal papers. Asiain and Mrquez (2009)show that several specimens in some particularColeoptera groups, are highly asymmetricallymodified and for this reason asymmetries arenot good characters for taxonomic work.Asymmetry is a good indicator that thischaracter is not possible to be valuated to
propose taxonomic changes (Mayr 1969).Cappe de Baillon (1927) and Balazuc (1948)studied and classified the teratological variation.Recent studies in highly polluted areas ofEurope has shown that some sensitive specieslike Frankliniella intonsa may be drasticallyaffected promoting an increase in the rate ofthese abnormalities and the majority of thesemonstrosities are associated with antennaldeformations (Vasiliu-Oromulu et al. 2008).
However, the abnormalities reported as a resultof environmental issues, reflected inembryological deformations in species such as
Frankliniella intonsa , are also found inspecimens collected in undisturbed systems intropical regions. This is the case of some speciesof Aeolothrips and Liothrips collected in CostaRica and in some specimens of Erotidothripsmirabilis collected in Asian national parks. It isnecessary, as has been done in other insectsgroups, to begin producing literature that reportsand illustrates these morphological changeswhich may lead to taxonomic errors inThysanoptera.
MOLECULAR DATA IN THYSANOPTERA
In several cases this kind of data are consideredthe panacea for all the taxonomic and
phylogenetic problems. But the real landscape isvery different. In some aspects molecular dataare more objective than traditional characters,
but in other aspects these molecular characters
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are inherently subjective (Lee 2004). Theconsiderations of some specialists that statemolecular data as being the solution to our
problems only denote little knowledge aboutthis topic.
Frequently the molecular data are not consistentwith the resolution. Same sets of data showvery different solutions and the question is whatis the truth? In reality, all the answers are true
because the inconsistency of the resolution ofdifferent sets of data is an effect of differentmethodologies for the study of the data matrix(Kjer et al. 2006, Klass 2007). In other casesthe molecular data concludes with resolutionswithout consistency with the biology of thegroup (Mound & Morris 2007)
Mound and Morris (2007) used molecular datato reconstruct the phylogeny of theThysanoptera. The only clear result that theseauthors obtained was the monophyly ofThysanoptera. The only arrangements withsupport for natural groups definition wasTubulifera and Terebrantia, the same twogroups defined by Haliday in 1836. The familygroups are not well supported and the classicalfamilies are not consistent natural groups. Theseresults are totally inconsistent with the
biological and morphological features. Severaltimes molecular studies have the sameimportance than a study in the Amazonia toconclude that this is a forest.
On the other hand, the molecular data needsgood support in morphological featuresassociated with the phylogenetic results,otherwise these results are inconsistent. Crespiand collaborators (2004) with molecular datamatrix conclude that in some groups as theclade formed by( Advenathrips +Vicinothrips )( Koptothrips (Triad othrips (Crespithrips (Glaridothrips + Xaniothrips))))) in the basal node of Koptothrips theenlarged forelegs character appears, which may
diagnose this group, but this character is notconstant in the species of this group. Studiesconducted in other arthropod groups haveconcluded that molecular data may indicate the
presence of genetic units with a high rate ofgenetic divergence which could indicate the
presence of undescribed species. However, it isunclear what level of divergence is needed forallowing the delimitation of two lineages(Camacho et al. 2011).
CONCLUSIONS
Thysanoptera is one of the highesthomoplasious groups such as Hymenoptera andHemiptera (Nieto 1999, Gauld & Mound 1982,Mound & Palmer 1983). Mound supposes thatthe operational difficulty with systematic studieson Phlaeothripinae is that many taxa at genericlevel and above are defined by loss ofapomorphous characters.
Gauld & Mound (1982) conclude that genera ingroups of insects with high levels of homoplasyneed to be defined polythetically, which isthrough the presence or absence of one or moreunique characters. About this point Mayr(1969) proposed three statements that need to besatisfied for a polythetic taxon: a) each species
possesses a large number of the total number ofcharacters of the taxon, b) each character is
possessed by a large number of the species andc) no characters are possessed by every speciesof the aggregate but is missing in the species ofall the other taxa.
The polythetic taxa created by Mound as Holopothrips does not follow the anteriorstatements and these genera defined in absenceof real characters are a big black box where the
biology and morphology needs to be reviewedfor a proper taxonomy of these species (Retana-Salazar & Nishida 2007).
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In the last years some authors considered thatgenitalia is not highly informative in thripstaxonomy, and only some structures highlyvariables as pseudovirga are more or less useful(Mound & Minaei 2007). This consideration isopposite to other data about morphologicalvariation derived from analysis of long series ofspecimens and the analysed together with thegeographic variation (Retana-Salazar 2006,2009). These opposite results are indicators ofthe complexity of thrips characters. Despite theconsiderations regarding the observations ofsome taxonomists, there is a big amount ofliterature that demonstrates the utility of themale genitalia in taxonomic works (Crdoba-Aguilar 2000).
Molecular data in Thysanoptera is not good fortaxonomic decisions and makes for poorcharacters in order to define biological groups(Mound & Morris 2007). Thysanoptera likeother groups, has several problems if moleculardata are considered as the best solution totaxonomic and phylogenetic problems.Molecular data is not the solution to taxonomicissues and the objectivity in some aspects of thiskind of data is accompanied by the subjectivityin other considerations (Lee 2004). The abilityof molecular data to determine species bygenetic similarity, remains valid if the species ofthe group are well known, at the same time, the
possibility of using molecular data to identifynew species appears to be an unreliabletechnique as well, if the data-bases are not largeenough or if taxonomic confirmations of theirwork are lacking (Meyer & Paulay 2005).
Teratological studies are necessary inThysanoptera because some erroneoustaxonomic decisions have been proposed usingthis kind of characters. In some other groups ofinsects these particular characters have beenstudied for the taxonomic significance of these(Asiain & Mrquez 2009). Goldarazena andcollaborators (2008) synonymyze the species
Nicolemma garitai with Aurantothripsorchidaceus based on teratological charactersand these decisions are not well founded andlead to grave mistakes in taxonomic work.These kinds of publications in sections used in
journals for discussion of particular areas ofconflict with few arguments destroy goodtaxonomic proposals for the sole comfort oftaxonomists.
We need a natural classification ofThysanoptera, but this group is highlyhomoplasius, the alternative is to carry out
phylogenetic studies that help us in thedefinitions of higher taxa and the study of the
phylogenetic inertia associated to characters thatshow us which features are good for thedefinition of natural groups that may beconsidered as taxa.
Several times specialists consider that thecharacters that are good in a particular groupmay be extrapolated to other taxa. In highlyhomoplasius groups this a priori consideration may conduce to consider as validartificial groups with homoplasius charactersused for their diagnosis.
Mound and Palmer (1981) published aninteresting paper where they analyzed eightmorphological characters in 50 genera ofThripini, they conclude that these features havea high taxonomic value and propose the
polarization of these characters based only onthe mere observation of specimens and inabsence of formal analysis. Based on thesecharacters these authors propose some genusgroups Frankliniella genus group, Thrips genusgroup, Taeniothrips genus group, Mycterothrips genus group and other. Recent studies based in
polarity of characters using fossil data and anew methodology to study the fossil insertion in
phylogenetic trees show that these charactersare not good for defining genus groups and arenot informative. Only two characters are useful
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for phylogenetic structure and both are plesiotypic and consequently not good fordetermination of natural groups (Retana-Salazar2008). That is an example of the problemscarried on with classification systems based ontaxonomic observation of characters in absenceof formal phylogenetic analysis.
Pealver and Nel (2010) have recently published an excellent paper about thetranscendent importance of the fossil evidencein determination of the contribution ofmorphological characters and based in theevidence and a new and better conducted
phylogenetic analysis conclude that the familyStenurothripidae needs to be considered a goodtaxon and an acceptable name better thanAdiheterothripidae. More evidence is needed tosupport this new hypothesis but at least this
proposal is solidly founded in data and formalanalysis. Previous studies have spurious
phylogenetic analysis where the repetition of theanalysis shows a different result to those thathave been published (Mound & Marullo 1998).
The only real tool to define hypothetical naturalgroups, based on the presence of apomorphouscharacters, is the phylogenetic reconstructionand the analysis of the phylogenetic inertia ofthe characters, that permits the consideration ofwhich characters are better to be used intaxonomic work. There arent any goodindicators for phylogenetic inertia of charactersin qualitative data sets, but some authors have
proposed the use of the retention index for thisevaluation (Bjrklund 1997, Diniz-Filho 2000).
Several times, with high complex groups likeThysanoptera, the parsimony analysis is not agood tool because the results of thereconstruction are a false clade, for this reasonBrooks & Wiley (1986) suggest the uses of theentropy concept in phylogeneticreconstruction as a way of evaluation of the
trees obtained. Recently Retana-Salazar &Retana-Salazar (2008) published a book wherethe uses of entropy in the study of biologicalsystems are proposed, particularly theevolutionary systems and the determination ofnew taxa.
ACKNOWLEDGEMENTS
To Ral Ramrez-Morales and Stephen Smithfor the English revision of this paper andAlexander Rodrguez-Arrieta for his commentsto this paper, and also The project Descripciny ultraestructura de los thrips (Thysanoptera:Insecta) de Mesoamrica 810 -A6-239 and the
project "Estudio morfolgico y gentico de losestados inmaduros de thrips (Thysanoptera:Insecta) de relevancia econmica enHispanoamrica", N810-Bl-224. Thecollections of the British Museum of NaturalHistory, London, England, SenckenbergMuseum, Frankfurt, Germany, MuseoGeominero de Madrid, Espaa, Collection deThysanoptera du Muse d'Histoire Naturelle deParis, National Collection of South Africa,Pretorya, South Africa, IBUNAM, Coyoacan,Mexico DF, Universidad Autnoma de laHabana, Cuba, Centro Nacional de SanidadVegetal de Cuba, Universidad AutnomaAgraria Antonio Narro, Coahuila, Mexico,Universidad Autnoma de Nayarit, Nayarit,Mexico, INBio, Santo Domingo de Heredia,Costa Rica. Alcides Snchez-Monge foroutstanding production of SEM images.
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Received: 10 de Diciembre 2011Reviewed: 03 de Febrero 2012Accepted: 23 de Agosto 2012.
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Figure 1. Topology obtained by applying a heuristic analysis of the data matrix presented by Mound et al.1980. Statistics L=144, CI=0.94, R=0,65, analysis performed with PAUP 3.1.1.
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Figure 2. Topology obtained by applying a heuristic analysis of the data matrix presented by Mound et al.1980. Statistics L=144, CI=0.94, R=0,65, analysis performed with PAUP 3.1.1.
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Figure 3. Best topology obtained by applying an exhaustive analysis of the data matrix presented by Moundet al. 1980. Statistics L=144, CI=0.94, R=0,65, analysis performed with PAUP 3.1.1.
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Figure 4. First topology proposed by Mound et al. 1980
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Figure 5. Second topology proposed by Mound et al . 1980
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Figure 6. Phylogenetic tree of groups of the Aeolothripidae published by Marullo and Mound (1995).
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Figure 7. Topology obtained by exhaustive analysis of the data matrix proposed by Marullo and Mound(1995). PAUP 3.1.1 was used.
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Figure 8. Taeniothrips inconsequens immature stage II abdominal segment IX, dorsal view. SEMmicrophotography, 300X, Hitachi 570S (scale: 5,5cm100m)
A B
Figure 9 . Frankliniella insularis . A) Adult female comb on VIII tergum, abdominal segments. SEMmicrophotography, 600X, Hitachi 570S (scale: 5,7cm50m). B) Immature stage II comb on IX tergum,abdominal segments. SEM microph otography, 600X, Hitachi 570S (scale: 5,7cm50m)
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A B
Figure 10. Thripidae antennal segments of immature stage II. A) Head and antennal segments I-II(Taeniothrips inconsequens , SEM microphotography, 500X, Hitachi 570S, scale: 5,7cm60m). B)Antennal segments III-VII ( Taeniothrips inconsequens , SEM microphotography, 700X, Hitachi 570S, scale:5,7cm43m).
A B
Figure 11. Aeolothrips intermedius . A) Antenna, immature stage II (SEM microphotography, 400X, Hitachi570S, scale: 5,7cm7 5m). B) Abdominal terga VIII-X, immature stage II (SEM microphotography, 400X,Hitachi 570S, scale: 5,5cm75m).