1. The Science of Plant Systematics
Plant Systematics (PBIO 309/509)
Harvey Ballard

2. Traditional Meaning of “Plant”
Autotrophs by photosynthesis
Chlorophyll A, B
Storage of carbohydrates (mostly starch)
Includes green algae (Chlorophyta) and land plants
Previously included fungi and related groups, these now removed as lineages nearer to animals

3. Plant Groups Covered in This Course
Extant land plants =
liverworts
hornworts
mosses
vascular plants (tracheophytes)
Course touches briefly on ferns & allies and gymnosperms
Focuses on
angiosperms
Judd et al. (2002)

4. What is Systematics?
Aims to recognize, describe, name, distinguish, relate and classify earth’s organisms
Borrows from other fields--very much a multidisciplinary, or “hybrid”, discipline
Supplies evidence to evolutionary biology, ecology and other fields
Fundamental to all other scientific endeavors (and many non-scientific human concerns)

5. Why is “Systematics” Fundamental?
Why do we give names to entities?
Who cares if different labs studying mutations in “Arabidopsis thaliana”, or investigating genetic disease in “chimpanzees”, work with the same organism across labs? How do we know?
How do we access information in libraries and museums, in computer or cabinet files, or on the internet?

6. What is Systematics? Uses diverse approaches: Molecular Biology
Morphology
Anatomy
Palynology
Microscopy
Biochemistry
Molecular Biology
Genetics
Physiology
Ecology
Evolution
Bioinformatics

7. Why is Systematics Important?
Detailed information at all hierarchical levels is key to most scientific fields, medicine and numerous aspects of human society
Names of taxa (e.g., species), or even individuals, are “tags” for information retrieval and knowledge synthesis

8. Why is Systematics Important?
Modern systematic studies provide biological context to evolutionary and ecological studies
Modern classifications are predictive, can guide bioprospecting for medicines, foods, etc.
Species-level information can guide conservation

9. The Practice of Systematics
Systematics sensu stricto
Determination of distinct taxa using diverse evidence
Inference of relationships using phenotypic or genetic data
Classification of taxa into larger groups
Production of systematic revisions, phylogenies, classification systems

10. The Practice of Systematics
Systematics sensu stricto
Name increasingly restricted to molecular systematics (more sexy, generally more fundable than unadulterated traditional studies), commonly focused at or above family level
Species-level systematics uncommon
Extras—evolutionary or biogeographic hypotheses can be addressed empirically
Common at larger universities, largest museums (few doing it)

11. The Practice of Systematics
Taxonomy
Nomenclature—application of names (follows international rules)
Characterization and distinction of taxa from field and herbarium studies
Production of monographs, floristic treatments, checklists
Common in herbaria and museums, small universities

12. The Practice of Systematics
Above two subdisciplines fall along a continuum
Many botanists fall into one or other “category”
Determined partly by resources of individuals and institutions—training, institutional aims, time, money
Collaboration spans chasms between molecular systematists who are not “experts” in a group and “experts” lacking resources to do molecular systematics

13. Phylogenetic Approach in This Course
Course uses current APG (Angiosperm Phylogeny Group) classification as framework to survey angiosperm families
Based heavily on Judd, et al.’s “Plant systematics—A phylogenetic approach”, 2nd ed. (2002), supplemented by Angiosperm Phylogeny Website, etc.
Facilitates understanding of evolutionary change “going up the tree”
Covers families in southeastern Ohio

14. The Phylogenetic Approach
Phylogeny--branching “tree” revealing relationships of taxa (species, genera, etc.)
Known taxa at branch tips, connected by hypothetical ancestors
Generated from diversity of data, commonly DNA sequences
More on algorithms later
Judd et al. (2002)

15. The Phylogenetic Approach
Three types of relationship possible
Monophyletic—common ancestor + all descendants (“natural”)
Paraphyletic—common ancestor + some descendants (“artificial”, generally rejected)
Polyphyletic--some descendants – ancestor (“artificial”, rejected)
Monophyletic groups the only “natural” taxa
Para- and polyphyletic groups demand shifting taxa around, or merging groups to achieve acceptable classification

16. The Phylogenetic Approach
A: monophyletic
B: paraphyletic
A+B: polyphyletic
Judd et al. (2002)

17. The Phylogenetic Approach
Genetic (DNA-based) data ideally used for phylogeny reconstruction where available
Molecular data (in form of As, Cs, Gs and Ts) provide numerous characters for evaluation of relationships
Molecular phylogeny provides non-circular basis for reexamining other evidence (e.g., phenotypic traits)
More on this later

18. The Phylogenetic Approach in Practice
Monophyletic groups retained
Others recircumscribed
Alternative “endpoints” along continuum
Lump all taxa in broader group
Subdivide more finely
Judd et al. (2002)

19. The Phylogenetic Approach in Practice
Example #1:
Monocots monophyletic
Monocots nested within dicots
Dicots paraphyletic with respect to monocots
Judd et al. (2002)

20. The Phylogenetic Approach in Practice
Basal Dicots
Solution to Example #1:
Retain Monocots
Recognize “Basal Monocot” lineages
Recognize “Eudicots”
Magnoliids
Monocots
Eudicots
Judd et al. (2002)

21. The Phylogenetic Approach in Practice
Basal Dicots
Solution to Example #1:
Higher-level groupings also supported by:
Embryology
Major biochemical compounds
Pollen types
Magnoliids
Monocots
Eudicots
Judd et al. (2002)

22. The Phylogenetic Approach in Practice
Example #2
Genus Hybanthus is 3rd largest in the Violaceae—up to 125 spp.
Similar in gross floral features, herb to shrub habit
H. concolor
(Barnes, photo)
H. communis
H. monopetalus
(Gordon, photo)

23. The Phylogenetic Approach in Practice
species worldwide
Diversity hotspots in N. Mexico, West Indies, S.E. Brazil/Paraguay, E. Africa and S. Australia

24. The Phylogenetic Approach in Practice
Pombalia (55-60 spp., Latin America)
Isodendrion
Hybanthus, s.str. (4 spp., Mesoamerica)
Hybanthus fruticulosus complex
Hybanthus thiemei complex
Agatea
Corynostylis
Anchietea
Melicytus, s.l.
Hybanthus enneaspermus complex
Viola
Noisettia
Allexis
Amphirrhox longifolia
Leonia
Gloeospermum
Orthion
Mayanaea
Cubelium (Hybanthus concolor,
Pigea (13 spp., S. Australia &
Paypayrola
Hekkingia
Rinorea crenata
Rinorea (other spp.)
Fusispermum
Passiflora (OUTGROUP)
(2 spp., Mexico)
(2 spp., Mesoamerica)
(ca spp., Africa to N. Australia)
New Caledonia)
E. North America)
Hybanthus is highly polyphyletic
Merger across family would lump extensive phenotypic diversity
Investigation of Hybanthus initiated

25. The Phylogenetic Approach in Practice
Pombalia (Latin America)
Isodendrion
Hybanthus, s.str. (Mesoamerica)
Hybanthus fruticulosus complex
Hybanthus thiemei complex
Agatea
Corynostylis
Anchietea
Melicytus, s.l.
Hybanthus enneaspermus complex
Viola
Noisettia
Allexis
Amphirrhox longifolia
Leonia
Gloeospermum
Orthion
Mayanaea
Cubelium (E.North America)
Pigea (S. Australia &
Paypayrola
Hekkingia
Rinorea crenata
Rinorea (other spp.)
Fusispermum
Passiflora (OUTGROUP)
(Mexico)
(Mesoamerica)
(Africa to N. Australia)
New Caledonia)
16 [12] 8
16, 32
[4]6-120
[4]6, 12, 24 24
24, 48
X = 8
X = 24
(6?)
Hybanthus groups differ dramatically in:
Flower symmetry
Stamen morphology
Seed morphology
Chromosome number
Pollen morphology
Xylem morphology
Similar only in
expanded bottom
petal

26. The Phylogenetic Approach in Practice
Trait: Corolla zygomorphy (lateral:bottom petal length ratio)
Pombalia [ ]
Hybanthus
H. fruticulosus complex
H. thiemei complex
H. enneaspermus comp
Cubelium
Pigea

27. The Phylogenetic Approach in Practice
Trait: Attachment of staminal glands on filament
medial
attachment
basal
attachment
Red line is
Base of
filament
H. fruticulosus H. enneaspermus Pigea
complex complex

28. The Phylogenetic Approach in Practice
Trait: Seeds, in relative size proportion
Pombalia Hybanthus H. fruticulosus
complex
H. thiemei H. enneaspermus Pigea Cubelium
complex complex

29. The Phylogenetic Approach in Practice
Summary of 12 Traits at a Glance
Pombalia
Hybanthus
H. fruticulosus comp.
H. thiemei comp.
H. enneasp. comp.
Cubelium
Pigea

30. The Phylogenetic Approach in Practice
“Cryptic” genera lumped earlier based on gross flower similarities
Clades are distinct biogeographic units
“Hybanthus” = 4 New World genera, 3 Old World ones
Each molecular clade = distinct genus
4 have earlier names, 3 require new ones

31. References
Judd, W. S., C. S. Campbell, E. A. Kellogg, P. F. Stevens, and M. J. Donoghue Plant systematics—A phylogenetic approach, 2nd ed. Sinauer Associates, Sunderland, MA. pp