Endosymbiosis

The origin of energy-conserving organelles, the mitochondria of all aerobic eukaryotes and the plastids of plants and algae, is commonly thought to be the result of endosymbiosis, where a primitive eukaryote engulfed a respiring -proteobacterium or a phototrophic cyanobacterium, respectively. While present-day heterotrophic protists can serve as a model for the host in plastid endosymbiosis, the situation is more difficult with regard to (the preceding) mitochondrial origin: Two chapters describe these processes and theories and inherent controversies. However, the emphasis is placed on the evolution of phototrophic eukaryotes: Here, intermediate stages can be studied and the enormous diversity of algal species can be explained by multiple secondary and tertiary (eukaryote-eukaryote) endosymbioses superimposed to the single primary endosymbiotic event. Steps crucial for the establishment of a stable, mutualistic relationship between host and endosymbiont, as metabolic symbiosis, recruitment of suitable metabolite transporters, massive gene transfer to the nucleus, development of specific translocases for the re-import of endosymbiont proteins, etc. are discussed in individual chapters. Experts, dealing with biochemical, genetic and bioinformatic approaches provide insight into the state of the art of one of the central themes of biology. The book is written for graduate students, postdocs and scientists working in evolutionary biology, phycology, and phylogenetics.

Part I The heterotrophic eukaryotes.-1. Mitochondria and the origin of eukaryotes, B. F. Lang, Montreal.- 2. Modifications and innovations in the evolution of the mitochondrial protein import pathways, V. Hewitt, T. Lithgow and R. F. Waller, Melbourne.- Part II Autotrophy as the driving force for endosymbiosis.- Primary endosymbiosis.-1. The single primary endosymbiotic event leading to the Archaeplastida, W. Loeffelhardt, Vienna.- 2. Insertion of metabolite transporters into the endosymbiont membrane(s) as a prerequisite for primary endosymbiosis, F. Facchinelli and A. P.M. Weber, Dusseldorf.- 3. Evolution of the protein translocon at the envelopes of chloroplasts, M. S. Sommer and E. Schleiff, Frankfurt.- 4. Evolution of storage polysaccharide metabolism in Archaeplastida opens an unexpected window on the molecular mechanisms that drove plastid endosymbiosis, S. Ball, Lille.- 5. Analysis of the genome of Cyanophora paradoxa: an algal model for understanding primary endosymbiosis, D. Bhattacharya, D. C. Price, Ch. X. Chan, J. Gross, J. M. Steiner and W. Loeffelhardt, Vienna.- 6. Photosynthetic Paulinella-recapitulation of primary plastid establishment, H. S. Yoon, E. Ch. Yang, H. Qiu and D. Bhattacharya, Suwon and New Brunswick.- 7. Rhopalodia gibba: The first steps in the birth of a novel organelle?, S. Adler, E. M. Trapp, C. Dede and U. G. Maier, Marburg.- 8. Secondary endosymbiosis, P. Gagat, P. Mackiewicz and A. Bodyl, Wroclaw.- 9. Chromera et al: Novel photosynthetic alveolates and apicomplexan relatives, M. Linares, D. Carter and S. B. Gould, Dusseldorf and Sydney.- 10. Nucleomorph comparative genomics, G. Tanifuji and J. M. Archibald, Halifax.- 11. Protein import into complex plastids: current findings and perspectives, C. Grosche, F. Hempel, K. Bolte, L. Abram, U. G. Maier and S. Zauner, Marburg.- 12. Tertiary plastid endosymbiosis in dinoflagellates, P. Gagat, P. Mackiewicz and A. Bodyl, Wroclaw.- 13. Endosymbioses in sacoglossan seaslugs: Photosynthetic animals that keep stolen plastids without borrowing genes, H. Wagele and W, F. Martin, Bonn and Dusseldorf.