[1]
Adamsa KL, Palmer JD. 2003. Evolution
of mitochondrial gene content: gene loss and transfer to the
nucleus. Molecular Phylogenetics and
Evolution, 29:380–395.文件编号: 03104.
[2]
Aguzzi A,Polymenidou M. 2004. Mammalian Prion
Biology: Review One Century of Evolving Concepts. Cell, 116:313-327.文件编号: 03063.
[3]
Archibald JM. 2005. Jumping Genes and Shrinking Genomes
– Probing the
Evolution of Eukaryotic Photosynthesis with Genomics. IUBMB
Life, 57(8): 539-547.文件编号: 03109.
[4]
Baluska F, Volkmann
D, Barlow PW. 2004.
Eukaryotic Cells and their Cell Bodies: Cell Theory Revised.
Ann. Bot, 94: 9-32.文件编号: 03112.
[5]
Barrette I, Poisson G, Gendron P, et al. 2001.
Pseudoknots in prion
protein mRNAs confirmed by comparative sequence analysis and
pattern searching Nucleic. Acids Res,
29(3):753-758.文件编号: 03052.
[6]
Beninati T,
Lo N, Sacchi L, et al.
2004. A Novel Alpha-Proteobacterium Resides
in the Mitochondria of Ovarian Cells of the Tick Ixodes
ricinus. Applied and Environmental
Microbiology, 70:2596–2602.文件编号: 03095.
[7]
Bernhard W, Leduc EH. 1967. Ultrathin
Frozen Sections: I. Methods
and Ultrastructural Preservation. J. Cell Biol,
34:757-771.文件编号: 03024.
[8]
Beveridge TJ. 1999. Structures of
Gram-Negative Cell Walls and Their Derived Membrane Vesicles.
J. Bacteriol, 181: 4725-4733.文件编号: 03071.
[9]
Bhattacharya D, Lutzoni F, Reeb V, et al. 2000. Widespread Occurrence of Spliceosomal Introns in the rDNA Genes of Ascomycetes. Mol.
Biol. Evol, 7(12):1971-1984.文件编号: 03041.
[10]
Bleiweis AS, Craig RA, Coleman SE, et al.
1971. The Streptococcal Cell Wall: Structure, Antigenic
Composition, and Reactivity with Lysozyme.
J. Dent. Res, 50:1118-1129.文件编号: 03028.
[11]
Blochl E, Rachel R, Burggraf S, et al. 1997. Pyrolobus
fumarii, gen. and sp. nov.,
represents a novel group of archaea,
extending the upper temperature limit for life to 113 degrees
C. Extremophiles, 1(1):14-21.文件编号: 03100.
[12]
Brockes JP. 1999. Topics in prion cell biology. Current Opinion in Neurobiology, 9(5):571-578.文件编号: 03001.
[13]
Brown S, Teplitz
M, Revel JP. 1974.
Interaction of Mycoplasmas with Cell Cultures, as Visualized by Electron
Microscopy. PNAS, 71:464-468.文件编号: 03032.
[14]
Cardone F, Pocchiari M,. 2001. A role for complement in transmissible
spongiform encephalopathies. Nature
Medicine, 7:410-411.文件编号: 03060.
[15]
Cavalier-Smith T. 2002. The neomuran
origin of archaebacteria, the negibacterial
root of the universal tree and bacterial megaclassification.
International Journal of Systematic and Evolutionary Microbiology,
52:7-76.文件编号: 03037.
[16]
Cavalier-Smith T. 2002. The phagotrophic
origin of eukaryotes and phylogenetic
classification of Protozoa. International Journal of Systematic
and Evolutionary Microbiology, 52:297-354.文件编号: 03058.
[17]
Cech TR. 2002. Ribozyme mechanisms and folding Ribozymes,
the first 20 years. Biochemical Society Transactions, 30:1162-1166.文件编号: 03039.
[18]
Claus GW, Roth LE. 1964. Fine Structure of the Gram-Negative
Bacterium Acetobacter suboxydans. J. Cell Biol, 20: 217-223.文件编号: 03072.
[19]
Cohen-Bazire G, Kunisawa
R. 1963. The fine
structure of Rhodospirillum rubrum. J cell Biol, 16:401-419.文件编号: 03126.
[20]
Cohen-Bazire G, Pfennig
N, Kunisawa R. 1964. The fine structure of green bacteria.
J cell Biol, 22: 207-225.文件编号: 03125.
[21]
Copley RR, Letunic
I, Bork P. 2001.
Genome and protein evolution in eukaryotes. Current Opinion
in Chemical Biology, 6:39-45.文件编号: 03002.
[22]
Costerton, JW Ingram JM, Cheng KJ. 1974. Structure and function of the cell
envelope of gram-negative bacteria. Microbiol.
Mol. Biol. Rev, 38: 87 - 110.文件编号: 05134.
[23]
Coulthart MB, Cashman NR. 2001. Variant Creutzfeldt-Jakob disease:
a summary of current scientific knowledge in relation to public
health. CMAJ, 165(1):51-58.文件编号: 03068.
[24]
Covert MW, Schilling CH, Famili I, et al. 2001.
Metabolic modeling of microbial strains in silico.
TrendS in Biochemical Sciences, 26(3):179-186.文件编号: 03030Metabolic network.
[25]
Daniel RA, Errington
J. 2003. Control
of Cell Morphogenesis in Bacteria: Two Distinct Ways to Make
a Rod-Shaped Cell . Cell, 113(6):767-776.文件编号: 03007.
[26]
Delwiche, CF. 1999. Tracing the
thread of plastid diversity through the tapestry of life. American
Naturalist, 154:S164-S177.文件编号: 03121.
[27]
Dmitriev B, Toukach F, Ehlers S. 2005. Towards
a comprehensive view of the bacterial cell wall. Trends in Microbiology,
13(12):569-574.文件编号: 03005.
[28]
Docampo R,
Moreno SNJ. 2001. The acidocalcisome. Molecular and Biochemical
Parasitology, 114(2):151-159.文件编号: 03014.
[29]
Doolittle, WF. 1999. Phylogenetic
Classification and the Universal Tree. Science, 284:2124-2128.文件编号: 03083.
[30]
Dyall SD,
Brown MT,
Johnson PJ. 2004.
Ancient invasions: from endosymbionts
to organelles. Science, 304:253-257.文件编号: 05133.
[31]
Dyall
SD,
Johnson PJ. 2000. Origins of
hydrogenosomes and mitochondria: evolution
and organelle biogenesis. Current Opinion in Microbiology, 3:404-411.文件编号: 03096.
[32]
Egelman EH. 2003. Cell Walls,
Cell Shape, and Bacterial Actin Homologs.
Developmental Cell, 5(1):4-5.文件编号: 03008.
[33]
Eikelenboom P, Bate C, Van Gool WA, et al. 2002. Neuroinflammation
in Alzheimer’s Disease and Prion
Disease. GLIA, 40:232-239.文件编号: 03055.
[34]
Emelyanov VV. 2003. Mitochondrial
connection to the origin of the eukaryotic cell. Eur.
J. Biochem, 270:1599-1618.文件编号: 03107.
[35]
Ferrer, I Blanco R, Carmona M, et al. 2001. Prion protein
expression in senile plaques in Alzheimer’s disease. Acta Neuropathol, 101:49-56.文件编号: 03054.
[36]
Fisher E, Telling G, Collinge J. 1998.
Prions and the prion
disorders. Mammalian Genome, 9:497-502.文件编号: 03051.
[37]
Fournier JG, Kopp N, Streichenberger N, et al. 2000. Electron microsocopy
of brain amyloid plaques from a patient
with new variant Creutzfeldt-Jakob disease. Acta
Neuropathol, 99:637-642.文件编号: 03045.
[38]
Frank L Heppner, Marco Prinz and Adriano Aguzzi. 2001. CHAPTER 55: Pathogenesis of prion diseases: possible implications of microglial cells. Progress in Brain Research, 132:737-750.文件编号: 03046.
[39]
Fujiwara S. 2002. Extremophiles:
Developments of their special functions and potential resources .
Journal of Bioscience and Bioengineering, 94:518-525.文件编号: 03016.
[40]
Gomez-Valero
L, Soriano-Navarro M, Perez-Brocal V, et al. . Coexistence of
Wolbachia with Buchnera
aphidicola and a Secondary Symbiont
in the Aphid Cinara cedri.
J. Bacteriol, 186: 6626-6633.文件编号: 03128.
[41]
Gray MW, Burger G, Lang BF.
2001. The origin and early evolution of mitochondria.
Genome Biology, 2(6):1018.1–1018.5.文件编号: 03105.
[42]
Gribaldo S, Philippe H. 2002. Ancient
Phylogenetic Relationships. Theoretical
Population Biology, 61:391-408.文件编号: 03091.
[43]
Guerrero R,
Pedros-Alio C, EsteveIsabe,
J, et al. 1986. Predatory
Prokaryotes: Predation and Primary Consumption Evolved in Bacteria.
PNAS, 83: 2138-2142.文件编号: 03082.
[44]
Hall WT, Claus G. 1963. Ultrastructural
studies on the blue-green algal symbiont
in Cyanophora paradoxa Korschikoff. J. Cell Biol, 19: 551–563.文件编号: 03124.
[45]
Harris DA. 1999. Cellular Biology of Prion Diseases. Clinical Microbiology Reviews, 12:429-444.文件编号: 03056.
[46]
Heddi A, Vallier A, Anselme
C, et al. 2005.
Molecular and cellular profiles of insect bacteriocytes:
mutualism and harm at the initial evolutionary step of symbiogenesis.
Cellular Microbiology, 7(2):293-305.文件编号: 03127.
[47]
Hoiczyk E, Hansel A. 2000. Cyanobacterial Cell Walls: News from an Unusual Prokaryotic
Envelope. Journal of Bacteriology, 182:1191-1199.文件编号: 03113.
[48]
Holt SC. 1978. Anatomy and chemistry
of spirochetes . Microbiol.
Mol. Biol. Rev, 42: 114 - 160.文件编号: 05135.
[49]
Horner DS, Heil B,
Happe T, et al. 2002. Iron hydrogenases-ancient
enzymes in modern eukaryotes .
Trends in Biochemical Sciences, 27(3):148-153.文件编号: 03012.
[50]
Huber H, Stetter
KO. 1998. Hyperthermophiles
and their possible potential in biotechnology. Journal of Biotechnology,
64:39–52.文件编号: 03103.
[51]
Hudson RG. 1999. Mesosomes:
A study in the nature of experimental reasoning. Philosophy
of Science, 66:289-309.文件编号: 03019.
[52]
Hughes AL. 1997.
Evolution of the proteasome components.
Immunogenetics, 46:82-92.文件编号: 03038.
[53]
Hutchison III, Clyde A, Peterson, Scott N. 1999. Global Transposon
Mutagenesis and a Minimal Mycoplasma
Genome. Science, 286:2165-2169.文件编号: 03129.
[54]
Jaenicke R, Sterner
R. 2002. Life at
High Temperatures. http://141.150.157.117:8080, .文件编号: 03099.
[55]
Janakiraman A, Goldberg MB. 2004.
Recent advances on the development of bacterial poles .
Trends in Microbiology, 12(11):518-525.文件编号: 03006.
[56]
JL, Pate, Johnson JL, Ordal EJ. 1967.
The Fine Structure of Chondrococcus
Columnaris: II. Structure and Formation of Rhapidosomes. J. Cell Biol, 35:15-35.文件编号: 03027.
[57]
Kandlera O, Konigb H. 1998. Cell wall polymers in Archaea (Archaebacteria). CMLS,
54:305-308.文件编号: 03035.
[58]
Karlberg O. 2004. Mitochondrial
evolution : turning bugs into features. Acta
Universitatis Upsaliensis,
2004:1-37.文件编号: 03097.
[59]
Katz LA. 1998. Changing perspectives on the origin
of eukaryotes. TREE, 13:493-497.文件编号: 03085.
[60]
Keeling PJ, Burger G, Durnford DG, Lang BF, et al. 2005. The tree of eukaryotes .
Trends in Ecology & Evolution, 20(12):670-676.文件编号: 03011.
[61]
Keeling PJ. 1998. A kingdom’s progress: Archezoa and the origin of eukaryotes. BioEssays,
20:87-95.文件编号: 03086.
[62]
Komachi K, Tung R. 2003. Essential Cell Biology: Chapter 1:
Introduction to Cells. Garland Science Publishing, 1-38.文件编号: 03004.
[63]
Kourie JI. 2002. Prion channel proteins and their role in vacuolation and neurodegenerative diseases. Eur Biophys J, 31:409-416.文件编号: 03050.
[64]
Kretzschmar HA. 1999. Molecular pathogenesis
of prion diseases. Eur
Arch Psychiatry Clin Neurosci,
249(S3):III/56-III/63.文件编号: 03049.
[65]
Kutschera U, Niklas KJ. 2004. The modern theory of biological evolution:
an expanded synthesis. Naturwissenschaften,
91:255-276.文件编号: 03089.
[66]
Kutscheraa U, Niklasb KJ. 2005. Endosymbiosis,
cell evolution, and speciation. Theory in Biosciences, 124:1-24.文件编号: 03090.
[67]
Levett PN. 2001. Leptospirosis. Clin. Microbiol. Rev, 14: 296 - 326..文件编号: 03130.
[68]
Liberski1 PP, Gajdusek DC,
Brown P. 2002. How
do neurons degenerate in prion diseases
or transmissible spongiform encephalopathies
(TSEs): neuronal autophagy
revisited. Acta Neurobiol.
Exp, 62:141-147.文件编号: 03069.
[69]
Lilley DMJ. 2003. The origins of RNA catalysis in ribozymes. Trends in Biochemical Sciences, 28:495-501.文件编号: 03040.
[70]
López-García P, Moreira D. 1999. Metabolic symbiosis at the origin
of eukaryotes., . TIBS, 24:88-93.文件编号: 03122.
[71]
Lutkenhaus J. 2002. Dynamic proteins
in bacteria. Current Opinion in Microbiology, 5(6):548-552.文件编号: 03009.
[72]
Madec JY, Vanier
A, Dorier A, et al. 1997. Biochemical properties of protease
resistant prion protein PrPsc
in natural sheep scrapie. Arch Virol,
142:1603-1612.文件编号: 03044.
[73]
Manson AL. 2002.
The Working Cell. Crash Course: Cell Biology and Genetics, 2nd
edition, 51-69.文件编号: 03003.
[74]
Margulis L,
Dolan MF, Guerrero
R. 2000. The chimeric eukaryote: Origin of the nucleus from the karyomastigont in amitochondriate
protists. PNAS, 97: 6954-6959.文件编号: 03115.
[75]
Margulis L. 1996. Archaeal-eubacterial mergers in the origin of Eukarya: Phylogenetic classification
of life. PNAS, 93: 1071-1076.文件编号: 03081.
[76]
Margulis L. 2004. Serial endosymbiotic theory (SET) and composite individuality. Transition
from bacterial to eukaryotic genomes. Microbiology Today, 31:
172-174.文件编号: 03118.
[77]
Martin W, Herrmann RG. 1998. Gene Transfer from Organelles to
the Nucleus: How Much, What Happens, and Why?.
Plant Physiology, 118: 9-17.文件编号: 03110.
[78]
Martin W, Hoffmeister
M, Rotte C, Henze
K. 2001. An Overview of Endosymbiotic
Models for the Origins of Eukaryotes, Their ATP-Producing Organelles
(Mitochondria and Hydrogenosomes),
and Their Heterotrophic Lifestyle. Biol. Chem,
382:1521-1539.文件编号: 03088.
[79]
Martin W, Russell MJ. 2003. On the origins
of cells: a hypothesis for the evolutionary transitions from
abiotic geochemistry to chemoautotrophic prokaryotes, and
from prokaryotes to nucleated cells. Phil. Trans. R. Soc. Lond.
B, 358:59-85.文件编号: 03106.
[80]
Martin W. 2003. Gene transfer from organelles to
the nucleus: Frequent and in big chunks. PNAS, 100: 8612-8614.文件编号: 03111.
[81]
McClendon JH. 1999. The origin of life. Earth-Science
Reviews, 47:71–93.文件编号: 03101.
[82]
McFadden, GI. 2001. Primary and secondary endosymbiosis and the origin of plastids. J. Phycol, 37:951-959.文件编号: 03120.
[83]
Meier P, Genoud N,
Prinz M, et al. 2003. Soluble Dimeric
Prion Protein Binds PrPSc
In Vivo and Antagonizes Prion Disease.
Cell, 113:49-60.文件编号: 03064.
[84]
Merlini G, Bellotti V. 2003. Molecular Mechanisms of Amyloidosis. N Engl J Med, 349:583-96.文件编号: 03061.
[85]
Meyer AS, Gillespie JR, Walther D, et al.
2003. Closing the Folding Chamber of the Eukaryotic Chaperonin
Requires the Transition State of ATP Hydrolysis. Cell, 113:369-381.文件编号: 03062.
[86]
Moreira D, Lopez-Garcia P. 1998.
Symbiosis Between Methanogenic Archaea and α-Proteobacteria as the Origin of Eukaryotes:
The Syntrophic Hypothesis. J Mol Evol, 47:517-530.文件编号: 03094.
[87]
Nand PK. 1997. Interaction of prion peptide HuPrP106-126 with nucleic acid. Arch Virol, 142:2537-2545.文件编号: 03047.
[88]
Nanninga N. 1968. Structural Features
of Mesosomes (Chondrioids)
of Bacillus Subtilis after Freeze-Etching.
J. Cell Biol, 39:251-263.文件编号: 03022.
[89]
Nanninga N. 1969. Preservation
of the Ultrastructure Of
Bacillus Subtilis by Chemical Fixation
as Verified by Freeze-Etching. J. Cell Biol,
42:733-744.文件编号: 03021.
[90]
Nelson KE, Clayton RA, Gill SR, et al.
1999. Evidence for lateral gene transfer between Archaea
and Bacteria from genome sequence of Thermotoga
maritima. Nature, 399:323-338.文件编号: 03034.
[91]
Newman HN, Britton AH. 1973. Ultrastructure
of Selected Bacteria Isolated from Dental Plaque as Revealed
by Freeze-Etching. J. Dent. Res, 52:1194-1201.文件编号: 03020.
[92]
Olsen GJ, Woese CR.
1993. Ribosomal RNA: a key to phylogeny. FASEB J, 7:
113-123.文件编号: 03077.
[93]
Palmer JD. 2003. The Symbiotic Birth and Spread of
Plastids: How Many Times and whodunit?.
J. Phycol, 39:4-11.文件编号: 03093.
[94]
Pate JL, Ordal EJ.
1967. The Fine Structure of Chondrococcus Columnaris: III. The
Surface Layers of Chondrococcus columnaris. J. Cell Biol, 35:37-51.文件编号: 03025.
[95]
Pate JL, Ordal EJ.
1967. The Fine Structure of Chondrococcus columnaris: I. Structure
and Formation of Mesosomes. J. Cell
Biol, 35:1-13.文件编号: 03026.
[96]
Pennisi E. 2004. The Birth of
the Nucleus. Science, 305:766-768.文件编号: 03084.
[97]
Philippe H, Forterre
P. 1999. The Rooting
of the Universal Tree of Life Is Not Reliable. Mol Evol,
49:509-523.文件编号: 03036.
[98]
Porter KR. 1984. The cytomatrix:
a short history of its study. J. Cell Biol,
99:3s-12s.文件编号: 03033.
[99]
Prusiner SB. 1997. Prion Diseases and the BSE Crisis. SCIENCE, 278:245-251.文件编号: 03065.
[100]
Rivera MC, Lake JA. 2004. The ring of life provides evidence
for a genome fusion origin of eukaryotes. Nature, 431:152-155.文件编号: 03092.
[101]
Roger AJ. 1999. Reconstructing Early Events in Eukaryotic
Evolution. The American Naturalist, 154:S146-S163.文件编号: 03087.
[102]
Rosenbaum RM, Wittner M. 1970.
Ultrastructure of Bacterized
and Axenic Trophozoites
of Entamoeba Histolytica with Particular
Reference to Helical Bodies. J. Cell Biol,
45: 367 - 382.文件编号: 03132.
[103]
Sedar AW, Burde RM. 1965. Localization of the Succinic Dehydrogenase System in
Escherichia Coli Using Combined Techniques of Cytochemistry
and Electron Microscopy. J. Cell Biol,
24:285-295.文件编号: 03029.
[104]
Sharp PM. 2002. Origins of Human Virus Diversity.
Cell, 108:305-312.文件编号: 03066.
[105]
Simpson S. 1999. Life’s First Scalding Steps: Biology
might have begun in cauldrons at the bottom of the sea. Sciencenews, 155(2):24.文件编号: 03102.
[106]
Sipe JD, Cohen AS. 2000.
History of the Amyloid Fibril. Journal
of Structural Biology, 130:88-98.文件编号: 03057.
[107]
Soto C. 1999. Alzheimer’s and prion disease as disorders of protein conformation: implications
for the design of novel therapeutic approaches. J Mol Med, 77:412-418.文件编号: 03043.
[108]
Soto C. 2002. Altering prion
replication for therapy and diagnosis of transmissible spongiform
encephalopathies. Biochemical Society Transactions, 30:569-574.文件编号: 03042.
[109]
Stossel TP. 1984. Contribution
of actin to the structure of the cytoplasmic
matrix. J. Cell Biol, 99:15s-21s.文件编号: 03031.
[110]
Tamm SL. 1982. Flagellated
ectosymbiotic bacteria propel a eucaryotic
cell. J. Cell Biol, 94: 697-709.文件编号: 03116.
[111]
Thomas NA, Bardy
SL, Jarrell KF. 2001.
The archaeal flagellum: a different kind of prokaryotic motility
structure. FEMS Microbiology Reviews, 25:147-174.文件编号: 03018.
[112]
Timmis JN, Ayliffe MA, Huang CY, et l. 2004. Endosymbiotic gene transfer: organelle genomes forge eukaryotic
chromosomes. Nature Reviews Genetics, 5:123-125.文件编号: 03108.
[113]
Tomasz A, Jamieson JD, Ottolenghi E. 1964. The Fine Structure of Diplococcus Pneumoniae. J. Cell
Biol, 22:453-467.文件编号: 03023.
[114]
Tompa P, Tusnady GE, Friedrich P, et al. 2002. The Role of Dimerization
in Prion Replication. Biophysical
Journal, 82:1711-1718.文件编号: 03070.
[115]
Turner BG, Summers MF. 1999. Structural Biology of HIV. J. Mol.
Biol, 285:1-32.文件编号: 03059.
[116]
Vellai T, Vida G. 1999. The origin
of eukaryotes: the difference between prokaryotic and eukaryotic
cells. Proceedings of the Royal Society of London Series B ,
266:1571-1577.文件编号: 03119.
[117]
Waggoner B. 2002. Eukaryotes and multicells:
Origin. Encyclopedia of Life Sciences, 6:585-593.文件编号: 03117.
[118]
Waites KB, Talkington DF. 2004. Mycoplasma
pneumoniae and Its Role as a Human
Pathogen. Clin. Microbiol. Rev, 17: 697-728.文件编号: 03131.
[119]
Walker LC, Bian F, Callahan MJ, et al. 2002. Modeling Alzheimer’s disease and
other proteopathies in vivo: Is seeding
the key?. Amino Acids, 23:87-93.文件编号: 03048.
[120]
Wheelis ML, Kandler O,Woese CR. 1992.
On the Nature of Global Classification
and CR Woese. PNAS, 89: 2930-2934.文件编号: 03078.
[121]
Wier A, Dolan M, Grimaldi D, et al. 2002. Spirochete and protist
symbionts of a termite (Mastotermes
electrodominicus) in Miocene amber. PNAS, 99:1410-1415.文件编号: 03114.
[122]
William Martin. 2005. Archaebacteria
(Archaea) and the origin of the eukaryotic
nucleus. Current Opinion in Microbiology, 8(6):630-637.文件编号: 03010.
[123]
Williams BAP, Keeling PJ. 2003. Cryptic Organelles in Parasitic Protists and Fungi. Advances in Parasitology,
54:9-68.文件编号: 03098.
[124]
Woese CR, Fox
GE. 1977. Phylogenetic Structure of the Prokaryotic Domain: The Primary
Kingdoms. PNAS, 74: 5088-5090.文件编号: 03080.
[125]
Woese CR. 1998. The universal
ancestor. PNAS, 95: 6854-6859.文件编号: 03076.
[126]
Woese CR. 2000. Interpreting
the universal phylogenetic tree. PNAS,
97: 8392-8396.文件编号: 03075.
[127]
Woese CR. 2002. On the evolution of cells. PNAS, 99: 8742-8747.文件编号: 03074.
[128]
Woese CR. 2004. A New Biology
for a New Century. Mol. Biol. Rev, 68: 173-186.文件编号: 03073.
[129]
Xu Y, Glansdorff N. 2002. Was our ancestor a hyperthermophilic procaryote? . Comparative Biochemistry and Physiology-Part A: Molecular
& Integrative Physiology, 133:677-688.文件编号: 03017.
[130]
Yang D, Oyaizu Y, Oyaizu H, et al.
1985. Mitochondrial Origins. PNAS, 82: 4443-4447.文件编号: 03079.
[131]
Yu SD, Kuenen JG. 2005. Haloalkaliphilic
sulfur-oxidizing bacteria in soda lakes. FEMS Microbiology Reviews,
29(4):685-702.文件编号: 03015.
[132]
Zaborowski1 A, Kordek R, Botts GT, et al. 2003.
Immunohistochemical Investigations
of the Prion Protein Accumulation
in Human Spongiform Encephalopathies. Pol J Pathol, 54(1):39-47.文件编号: 03067.
[133]
Zahn R. 1999. Prion propagation and molecular chaperones. Quarterly Reviews
of Biophysics, 32:309-370.文件编号: 03053.
[134]
Zerges W. 2002. Does complexity
constrain organelle evolution? .
Trends in Plant Science, 7(4):175-182.文件编号: 03013.
[135]
Zientz, E,
Silva FJ, Gross R. 2001. Genome interdependence
in insect-bacterium symbioses. Genome Biology, 2:1032.1-1032.6.文件编号: 03123.