1. Insect Phylogeny and Evolution

2. Determining Phylogenetic Relationships
No engine, two wheels
Gas engine, two wheels
Gas engine, four wheels, no box on back
Diesel engine, four wheels, solid box on back
Gas engine, four wheels, glassed box on back
No engine, one wheel
Gas engine, four wheels, solid box on back

3. Determining Phylogenetic Relationships
bicycle
unicycle
motorcycle
SUV
sedan
van
truck
No engine, two wheels
Gas engine, two wheels
glass
solid
Gas engine, four wheels, no box on back
Box
No box
Diesel engine, four wheels, solid box on back
4 wheels
2 wheels
2 wheels
1 wheel
Gas engine, four wheels, glassed box on back
Gas
Diesel
No engine, one wheel
No engine
Engine
Gas engine, four wheels, solid box on back
Some ancestral vehicle (??)

4. Determining Phylogenetic Relationships
motorcycle
bicycle
unicycle
SUV
sedan
van
truck
Species - 7
glass
solid
Genus - 6
Family - 5
Box
No box
Order - 4
Phylum - 2
4 wheels
2 wheels
2 wheels
1 wheel
Gas
Diesel
No engine
Engine
Some ancestral vehicle (??)

5. A little bit about taxonomy, classification and phylogeny
Systematics - study of the diversity and relationships of organisms both now and in the past.
Taxonomy - classification, naming and description of taxa.
Phylogeny - The evolutionary development and history of a species or higher taxonomic grouping of organisms.

6. Methods of establishing phylogenies
Evolutionary systematics
Phenetics
Cladistics
Evolutionary systematics - use several fixed levels of a hierarchy, such as kingdom, phylum, class, order, and family.

7. Methods of establishing phylogenies
Evolutionary systematics
Phenetics
Cladistics
Phenetics (numerical taxonomy)
- based on taking lots of measurements on organisms & then using computer algorithms to assign relationships among them
Robert R. Sokal
Problems - ignored ancestral vs. derived characteristics
C.D. Michener

8. Methods of establishing phylogenies
Evolutionary systematics
Phenetics
Cladistics
Cladistics - classifies species of organisms into hierarchical monophyletic groups (clades) - based on shared derived characteristics (or characters)
e.g. Character #1 - present in species A, B, C
Willi Hennig
Character #2 - present in species A, B, but not C
 Have 2 groups - A + B and C

9. Methods of establishing phylogenies
Evolutionary systematics
Phenetics
Cladistics
Some definitions
Plesiomorphy -or ancestral character that is present at the base of the tree. For example, the presence of six legs (shared by all insects) can be hypothesized to have existed in some common insect ancestor.
Apomorphy - derived state is a characteristic believed to arisen in a recent common ancestor or a recently evolved feature that appears only in a group of closely related species. The elytra of that all beetles have serve to separate them from all insects

10. Methods of establishing phylogenies
Evolutionary systematics
Phenetics
Cladistics
Some more definitions
Monophyletic groups - contain ancestor and all descendant species
Paraphyletic groups - contain ancestor and some but not all descendant species
Polyphyletic groups - contain taxa from two or more different monophyletic groups

11. PARTIAL CLASSIFICATION OF DIPTERA
MONOPHYLETIC
PARAPHYLETIC
POLYPHYLETIC

12. Phylogeny of the Arthropoda
Onychophora
Annelid-like
ancestor
Tardigrada
Marellomorpha †
Arachnidomorpha(≈Chelicerata)
Crustaceomorpha
Next slide
Arthropoda
Atelocerata
These taxa are all subphyla of Arthropoda

13. † † † † † Phylogeny of the Mandibulata
Chelicerates (spiders, scorpions, mites etc.) †
= terrestrial origin † †
Crustacea
Chilopoda
Symphyla
Pauropoda
Mandibulata
Diplopoda †
Atelocerata
(possess trachea) †
Entognatha
Hexapoda
Insecta

14. Non-Hexapod Mandibulates
Chilopoda - centipedes
Symphla
Pauropoda
Diplopoda- millipedes

15. Summary of features of non-hexapod mandibulates
Size # of pairs of legs # of segments # m.p.’s
Chilopoda cm pr
Symphyla < 1.0 cm pr
Pauropoda cm pr
Diplopoda < 5 cm < 200 < pr

16. Relationships among Hexapoda
Collembola
Entognatha
Protura
Diplura
Hexapoda
Archaeognatha
Insecta
Thysanura
Pterygota

17. Hexapoda Insecta Pterygota Neoptera Holometabola Apterygotes
Silurian
Devonian
Carboniferous
Permian
Triassic
Jurassic
Cretaceous
Entognatha
Archaeognatha
Hexapoda
Zygentoma
Ephemeroptera
Insecta
Odonata
Plecoptera
Embiodea
Pterygota
Zoraptera
Dermaptera
Grylloblattodea ?
Mantophasmatodea
Orthoptera
Phasmatodea
Blattaria
Isoptera
Mantodea
Neoptera
Psocoptera
Phthiraptera
Thysanoptera
Hemiptera
Coleoptera
Rhaphidioptera
Megaloptera
Neuroptera
Hymenoptera
Holometabola
Mecoptera
Siphonaptera
Diptera
Apterygotes
Strepsiptera
Trichoptera
Paleoptera
Lepidoptera
Hemimetabolous
Holometabolous

18. Vascular plants Seed plants
Silurian
Devonian
Carboniferous
Permian
Triassic
Jurassic
cretaceous
Entognatha
Archaeognatha
Zygentoma
Ephemeroptera
Insecta
Odonata
Plecoptera
Embiodea
Pterygota
Zoraptera
Dermaptera
Grylloblattodea ?
Mantophasmatodea
Orthoptera
Phasmatodea
Blattaria
Isoptera
Mantodea
Neoptera
Psocoptera
Phthiraptera
Thysanoptera
Hemiptera
Coleoptera
Rhaphidioptera
Megaloptera
Neuroptera
Hymenoptera
Holometabola
Mecoptera
Siphonaptera
Diptera
Strepsiptera
Trichoptera
Lepidoptera
Vascular plants Seed plants

19. 1 2 3 4 Steps in arthropod evolution Common ancestor - legless annelid
- undifferentiated body 2
Paired bilateral appendages
- development of somites, antennal segments, and simple eyes (like Onychophora) 3 4
3. Early arthropod - better developed eyes and jointed legs
Reduction in appendages
- cephalization
-modification of first appendages into mouthparts
- development of three tagmata

20. What about the Onychophora (“velvet worms” )?
Annelid Arthropod
Characteristics Characteristics
-worm-like body -segmented legs
(during
embryogenesis)
Peripatus
-paired nephridia -open circulatory system
- hemocoel
- trachea
- oral appendages

21. Evolution of the Insects
(Carpenter )
Four stages in insect evolution
4. Development of metamorphosis
3. Development of wing flexion mechanisms
2. Development of wings
1. Appearance of primitive wingless insects