The sperm structure of the Scraptiidae (Coleoptera; Tenebrionoidea)

The sperm ultrastructure of two members of the Scraptiidae Anaspis pulicaria and A. lurida was studied. The results confirm the general organization of the sperm in the superfamily Tenebrionoidea. The sperm bundles at the end of the spermiogenesis show the same peculiar antiparallel distribution at the two opposite poles of the germ cyst, observed in other Tenebrionoidea. The sperm have a bi-layered acrosome, a long cylindrical nucleus with two infoldings at its basal region, two elliptical equal mitochondrial derivatives and two triangular accessory bodies. The flagellar axoneme has the common 9 + 9 + 2 microtubular pattern that at the tail end results disorganized. All these sperm characteristics are quite similar to those found in Pythidae, a closely related family, according to molecular data.

The sperm ultrastructure of members of basal Tenebrionoidea (Coleoptera)

The sperm ultrastructure of some beetles of Tenebrionoidea was studied with particular attention to those of the Ripiphoridae, Mordellidae, and Meloidae. These three groups are often thought to form a clade, which is the sister group of the remaining Tenebrionoidea. The testes of the two former families have thinner but longer spermatic cysts containing fewer and longer sperm. Within each cyst all sperm cells have the same orientation, but cross sections showed that the orientation of the axonemes alternate between adjacent cysts, possibly due to the cysts bending on themselves. In both families the sperm has a bilayered acrosome and the flagellum, which shows mitochondrial derivatives starting laterally to the nuclear base, has a typical 9 + 9+2 axoneme with accessory tubules provided with 16 protofilaments in their wall, and well-structured triangular shaped accessory bodies. In Mordellistena sp (Mordellidae) sperm, both mitochondrial derivatives and accessory bodies are somewhat asymmetrical. Moreover, the flagellum shows a very thin and long tail end provided with only accessory tubules. Meloidae species have testes with thicker sperm cysts containing numerous shorter sperm. Within the individual cysts the sperm flagella exhibit an alternating orientation of their axonemes as consequence of a peculiar spermatogenetic process. The flagellar structure is similar to that of the above-mentioned species, but the accessory bodies are not well defined and constituted by fuzzy material. In Mylabris hieracii (Meloidae) sperm, the acrosome is flat with a conspicuous perforatorium and its nucleus has a peculiar quadrangular section. Berberomeloe majalis sperm has a large acrosome with an unusual pentagonal perforatorium. The centriolar structure of Mylabris variabilis shows a complex of dense radial links connecting the microtubular structures to the plasma membrane. These results suggest that Ripiphoridae have a closer relationship with Mordellidae than with Meloidae. These findings are in agreement with results obtained with molecular data.

The sperm ultrastructure of Pytho depressus (Linnaeus, 1767) (Coleoptera, Pythidae)

The sperm ultrastructure of Pytho depressus (Pythidae) is described in this study. The sperm are short cells, about 85-90 μm long, with an acrosome consisting of three layers, a cylindrical nucleus, which at its base has the initial region of two mitochondrial derivatives. The flagellum has two well-developed triangular accessory bodies, and a 9 + 9+2 axonemal pattern with accessory tubules provided with 16 protofilaments in their wall. The structure and shape of the accessory bodies are diagnostic characters within the superfamily. The sperm morphology of P. depressus can be easily distinguished from those of Ripiphoridae, Meloidae and Tenebrionidae. The P. depressus sperm are organized in cysts as in other species of the group but the sperm are not well aligned and show an antiparallel orientation, a feature also observed in other tenebrionids. The phylogenetic implications of the observed sperm features are discussed in the context of comparative sperm ultrastructure of other insect species.

Early Cretaceous origin of pollen-feeding beetles (Insecta: Coleoptera: Oedemeridae)

The taxonomic position of a new pollen-feeding fossil beetle from Spanish amber (late Albian, 105 Ma) is analysed. A phylogenetic analysis allows me to accommodate Darwinylus marcosi gen. et sp. nov. in the Polyphaga: Oedemeridae within current limits for the family, which clearly belongs in the subfamily Oedemerinae. It corresponds to the oldest definitive record for the family. Some autapomorphies, mainly in antennae, are observable in the fossil compared with extant members of the family. A discussion about these problematic characters and the evolution of the family is proposed.

Conflict, convergent evolution, and the relative importance of immature and adult characters in endopterygote phylogenetics

We use two episodes from systematic history to illustrate how conflict between immature and adult data was important for the development of phylogenetic systematics. A reference search in Zoological Record reveals that most phylogenetic analyses of endopterygote insects continue to utilize morphological rather than DNA sequence data. However, the use of immature and adult data is established for only a few taxa. An assessment of the phylogenetic utility of 73 matrices with immature and adult data reveals that the immature partitions have fewer characters and that immature characters provide lower node support through homoplasy levels in immatures, and adult partitions are comparable. Despite much conflict, analyses based on all available evidence yield better tree resolution and higher support. We argue that DNA sequence-based matching of immature and adult stages will greatly help with the study of endopterygote immatures and facilitate the assembly of combined character matrices with data from all life-history stages.

Southern Hemisphere Biogeography Inferred by Event-Based Models: Plant versus Animal Patterns

The Southern Hemisphere has traditionally been considered as having a fundamentally vicariant history. The common trans-Pacific disjunctions are usually explained by the sequential breakup of the supercontinent Gondwana during the last 165 million years, causing successive division of an ancestral biota. However, recent biogeographic studies, based on molecular estimates and more accurate paleogeographic reconstructions, indicate that dispersal may have been more important than traditionally assumed. We examined the relative roles played by vicariance and dispersal in shaping Southern Hemisphere biotas by analyzing a large data set of 54 animal and 19 plant phylogenies, including marsupials, ratites, and southern beeches (1,393 terminals). Parsimony-based tree fitting in conjunction with permutation tests was used to examine to what extent Southern Hemisphere biogeographic patterns fit the breakup sequence of Gondwana and to identify concordant dispersal patterns. Consistent with other studies, the animal data are congruent with the geological sequence of Gondwana breakup: (Africa(New Zealand(southern South America, Australia))). Trans-Antarctic dispersal (Australia <--> southern South America) is also significantly more frequent than any other dispersal event in animals, which may be explained by the long period of geological contact between Australia and South America via Antarctica. In contrast, the dominant pattern in plants, (southern South America(Australia, New Zealand)), is better explained by dispersal, particularly the prevalence of trans-Tasman dispersal between New Zealand and Australia. Our results also confirm the hybrid origin of the South American biota: there has been surprisingly little biotic exchange between the northern tropical and the southern temperate regions of South America, especially for animals.