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Tegeticula

Olle Pellmyr *

Yucca moths

     =========================== T. maculata 
     |
     |  ======================== T. synthetica 
     |  |
     |  |     ================== T. treculeanella 
     |  |  ===|
     |  |  |  ================== T. carnerosanella 
     |  |  |
     |  |  |  ================== T. maderae 
     |  |  |  |
     |  |  |  |  =============== T. mojavella 
     |  |  |  |  |
     |  |  |  |  |           === T. altiplanella 
     |  |  |  |  |        ===|
<<===|  |  |  |  |  ======|  === T. baccatella 
     ===|  |  |  |  |     |
        ===|  |  |  |     ====== T. rostratella 
           |  |  |  |
           ===|  |  |     ====== T. superficiella 
              ===|  |=====|
                 ===|     ====== T. elatella 
                    |
                    |=========== T. corruptrix 
                    |
                    |        === T. cassandra 
                    |     ===|
                    ======|  === T. intermedia 
                          |
                          ====== T. yuccasella

Based on Pellmyr et al (1996) and Pellmyr & Leebens-Mack, in press

Containing clade(s): Prodoxidae top

Table of Contents

Introduction
Characters of Tegeticula
Life habits of immature stages
Geographic distribution
Discussion of Phylogenetic Relationships
References
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Introduction

Tegeticula is one of the two genera of true yucca moths, which offer one of the classical cases of coevolved obligate mutualism between species. Females use unique tentacles on their maxillary palps to actively collect and compact pollen from the flowers of their yucca hosts. Yucca pollen is very sticky, and it adheres (without aid of the tentacles) to the underside of her head. Once loaded, the female oviposits into yucca flowers, walking up to floral stigmas after oviposition and actively pollinating the flower with a small portion of her pollen batch. In so doing, she assures that lack of pollination will not cause the flower to abort. This is critical, because her progeny feed only on developing seeds. The larvae only feed on a modest proportion of the seeds, thus making it possible for this herbivore to actually be of net benefit to its host. Over evolutionary time, yucca moths and yuccas have evolved complete mutual dependence on each other (Riley 1892, Pellmyr et al 1996b).

A considerable body of literature has accumulated on ecological and evolutionary aspects of the yucca-yucca moth interaction; a comprehensive reference list for the early literature is provided in Davis (1967), and much of the subsequent work is referenced in Powell (1992) and Pellmyr et al (1996). Recent empirical work has focused on the stability of obligate mutualism (Pellmyr and Huth 1994, Richter and Weis 1995), reversal of mutualism (Pellmyr et al 1996a), and moth behavioral plasticity in pollination and egg dispersal decisions (Addicott and Tyre 1995).

Recently the species traditionally called T. yuccasella has been identified as being a complex of at least 13 species, many of which have very distinctive biology. Among them are two non-pollinating species of 'cheater yucca moths'. The reader should bear in mind that many papers written before the recent revision that provide, e.g., measures of seed consumption, actually provide composite measurements of all coexisting species. This problem only applies to the yuccasella complex ("the white species").

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Characters of Tegeticula

Tegeticula shares one synapomorphy with Parategeticula:

Two traits that distinguish Tegeticula from Parategeticula are:

Maxillary tentacles and pollen load of T. carnerosanella, a species in the Tegeticula yuccasella complex

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Life habits of immature stages

Tegeticula females oviposit into floral ovaries or developing fruits, and the grublike larvae feed of developing seeds. Usually white during the early instars, the larvae turn pink or to dark red when reaching later instars. The larva bores out through the fruit wall upon maturity, and creates a thick cocoon in the soil. It diapauses, sometimes for more than one year, and pupation apparently takes place a few weeks or less before adult emergence. The pupa is equipped with a frontal protrusion and large spines on the abdominal segments, which serve in burrowing up to the ground surface.

A last-instar larva of T. treculeanella, a member of the yuccasella complex.

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Geographic distribution

The range of Tegeticula closely matches the extant distribution of their yucca hosts. This includes the extended ranges of yuccas in interior eastern North America, where European settlers introduced yuccas over the last 150 years. The northern limit of the genus is now in southern Alberta and Ontario in Canada. The southernmost records are from Tehuacan in Puebla, Mexico (Davis 1967).

Riley shipped larvae to Europe in an attempt to introduce yucca moths, but there is no report of success.

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Discussion of Phylogenetic Relationships

The phylogenetic relationship between the three historically recognized species has only been considered in an analysis based on mitochondrial DNA sequence data (Pellmyr et al 1996). The topology is very strongly supported in that analysis. Phylogenetic resolution provided here is based on data from a paper to appear in the American Naturalist (Pellmyr & Leebens-Mack in press). There is evidence of a rapid radiation event within this group, and relationships among the biologically diverse lineages is not yet clear.

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References

Addicott, J.F and A.J. Tyre. 1995. Cheating in an obligate mutualism: 
          How often do yucca moths benefit yuccas? Oikos 72:382-394.
Davis, D.R. 1967. A revision of the moths of the subfamily  Prodoxinae 
          (Lepidoptera: Incurvariidae). U.S. Nat. Hist. Mus., 
          Bull.  255:1-170.
Frack, D.C. 1982. A systematic study of prodoxine moths (Adelidae: 
          Prodoxinae) and their hosts (Agavaceae), with descriptions 
          of the subfamilies of Adelidae (s. lat.). M.S. thesis, 
          California State Polytechnic University, Pomona, CA.
Pellmyr, O. & C.J. Huth. 1994. Evolutionary stability of mutualism 
          between yuccas and yucca moths.  Nature 372:257-260.
Pellmyr, O. & J. Leebens-Mack. Reversal of mutualism as a mechanism 
          of radiation in yucca moths. Amer. Nat., in press.
Pellmyr, O., J. Leebens-Mack & C.J. Huth. 1996a. Non-mutualistic 
          yucca moths and their evolutionary consequences. Nature 
          380:155-156.
Pellmyr, O., J.N. Thompson, J. Brown & R.G. Harrison. 1996b. 
          Evolution of pollination and mutualism in the yucca 
          moth lineage.  Amer. Nat. 148:827-847.
Powell, J.A. 1992. Interrelationships of yuccas and yucca moths. 
          TREE 7:10-15.
Richter, K.S. and A.E. Weis. 1995. Differential abortion in the 
          yucca. Nature 376:557-558.

About this page

Olle Pellmyr
E-mail: pellmyr@ctrvax.vanderbilt.edu.
Dept of Biology, Box 1812-B Vanderbilt Univ, Nashville, TN 37235, USA

Page copyright © 1996 Olle Pellmyr

First online 13 January 1997
Last saved 14 January 2000

Title Illustrations

Left: Tegeticula yuccasella, a member of the yuccasella complex actively pollinating a host flower.
Right: T. synthetica resting in a host flower.

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