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Biology 332 -
Protistology - Supplemental References |
| Group
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Topic
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Reference
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| Cryptomonads
|
symbiosis evolution |
McFadden, G.I. 1990.
Evidence that chryptomonad chloroplasts evolved from eukaryotic endosymbionts. J. Cell
Sci. 95, 303-308. |
| Cryptomonads |
symbiosis evolution
|
MsFadden, Gilson, P.R.,
and Douglas, S.E. 1994. The photosynthetic endosymbiont in cryptomonad cells produces both
chloroplast and cytoplasmic-type ribosomes. J. Cell Sci. 107, 649-57. |
| Cryptomonads Chromists |
phylogeny |
McFadden, G.I., Gilson,
P.R., and Hill, D.R. 1994. Goniomonas: rDNA sequences indicate that this phagotrophic
flagellate is a close relative of the host component of cryptomonads. Eur. J. Phycol. 29,
29-32. |
| Cryptos |
phylogeny, structure
|
Douglas, S.E , Murphy,
C.A., Spencer, D.F. and Gray, M.W. 1991. Cryptomonad algae are evolutionary chimeras of
two phyletically distinct unicellular eukaryotes. Nature 350, 148-151. |
| Cryptos |
phylogeny |
Eschbach, S. et al.
1991. Primary and secondary structures of the nuclear small subunit ribosomal of the
cryptomonad Pyrenomonas salina as inferred from gene sequence: Evolutionary
implications. J. Mol. Evol. 32, 247-252. |
| Cryptos |
structure |
Gillot, M.A. and Gibbs,
S.P. 1983, Comparison of the flagellar rootlets and periplast in two marine cryptomonads.
Can. J. Bot. 61, 1964-1978. |
| Cryptos |
structure |
Hansman, P. 1988.
Ultrastructural localization of RNA in cryptomonads. Protoplasma 146, 81-88. |
| Cryptos |
|
Hill, D.R.A. 1991. The
diversity of heterotrophic cryptomonads. In: Patterson, D.J. and Larsen, J. (eds.) The
Biology of Free-living Heterotrophic Flagellates. Clarendon Press. Oxford. pp.
235-240. |
| Cryptos |
structure |
Kugrens, P. and Lee,
R.E. 1991. The organization of Cryptomonads. In: Patterson, D.J. and Larsen, J. (eds.) The
Biology of Free-living Heterotrophic Flagellates. Clarendon Press. Oxford. pp.
219-234. |
| Cryptos, chrysos,
chromophytes, chloroplasts |
origin, phylogeny |
Cavalier-Smith, T.,
Allsopp, M.T.and Chao, E.E. 1994. Chimeric conumdra: are nucleomorphs and chromists
monophyletic or polyphyletic. PNAS U.S.A. 91-11368-11372. |
| Cryptos, nucleomorph |
evolution |
Gibbs. S.P., and M.
Ludwig. 1984. DNA is present in the nucleomorph of cryptomonads: Further evidence that the
chloroplast evolved from a eukaryotic endosymbiont. Protoplasma 127, 9-20. |
| Cryptos, nucleomorph |
structure, evolution |
Gillot, M.A. and Gibbs,
S.P. 1980. The cryptomonad nucleomorph: Its ultrastructure and the evolutionary
significance. J. Phycol. 16, 558-568. |
| cryptos, nucleomorph |
origin, phylogeny,
nucleomorph |
Ludwig, M. and Gibbs,
S.P. 1985. DNA is present in the nucleomorph of cryptomonads: Further evidence that the
chloroplast evolved from a eukaryotic symbiont. Protoplasma 127, 9-20. |
| Cryptos, nucleomorph |
structure, phylogeny |
Maier, U.G. et al.
1991. Demonstration of nucleomorph encoded eukaryotic small subunit ribosomal RNA in
cryptomonads. Mol. Gen. Genet. 1-7 (vol. not given) |
| Cryptos, prasinos |
structure, trichocysts
|
Morrall, S. and A.D.
Greenwood. 1980. A comparison ofthe periodic substructure of the trichocysts of the
Cryptophyceae and Prasinophyceae. BioSystems 12, 71-83. |
| reds |
phylogeny |
Hendriks. L. et al.
1989. The evolutionary position of the rhodophyte Porphyra umbilicalis and the
basidiomycete Leucosporidium scottii among other eukaryotes deduced from complete
sequences of small ribosomal subunit RNA. J. Mol. Evol 32, 167-177. |
| reds, chloroplasts |
evolution |
Marcowitz, Y. and
Loiseaux-de Goer. 1991. Plastid genomes of the Rhodophyta and Chromophyta constitute a
distinct lineage which differs from that of the Chlorophyta and have a composite
phylogenetic origin, perhaps like that of the Euglenophyta. Current Genetics 20,
427-430. |
| Reds, rhodophytes |
phyligeny |
Bhattacharya, D.,,
Elwood, H.J., Goff, L.J. and Sogin, M.L. 1990. Phylogeny of Gracilaria lemaniformis
(Rhodophyta) based on sequence analysis of its small subunit ribosomal RNA coding region.
J. Phycol. 181-186. |
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