Page 246 - The Biochemistry of Inorganic Polyphosphates

P. 246

WU095/Kulaev
WU095-Ref
References
230 March 9, 2004 15:57 Char Count= 0
of the ‘phosphate overplus’ phenomenon in Plectonema boryanum. Can. J. Mirobiol., 20, 1235–
1239.
T. E. Jensen, L. Sicko-Goad and R. P. Algala (1977). Phosphate metabolism in blue–geen algae. III.
The effect of ﬁxation and post-staining on the morphology of polyphosphate bodies in Plectonema
boryanum. Cytologia, 42, 357–369.
T. E. Jensen, M. Baxter, J. M. Rachlin and V. Jani (1982). Uptake of heavy metals by Plectonema
boryanum (Cyanophyceae) into cellular components, especially polyphosphate bodies; an X-ray
energy dispersive study. Envinron. Poll., A27, 119–127.
C. O. Jeon, D. S. Lee and J. M. Park (2003). Rhodocyclus and Proteobacteria microbial communities
in activated sludge performing enhanced biological phosphorus removal in a sequencing batch
reactor. Water Res., 37, 2195–21205.
M. S. M. Jetten, T. J. Fluit, A. J. M. Stams and A. J. B. Zehnder (1992). A ﬂuoride-sensitive inorganic
pyrophosphatase isolated from Methanothrix soehngenii. Arch. Microbiol., 157, 284–289.
H. E. Jones, I. B. Holland, A. Jacq, T. Wall and A. K. Campbell (2003). Escherichia coli lacking the
AcrAB multidrug efﬂux pump also lacks nonproteinaceous, PHB–polyphosphate Ca 2+ channels
in the membrane. Biochim. Biophys. Acta, 1612, 90–97.
J. Jordanov, J. Grigorov and A. Bojadjieva-Michaijlova (1962). ¨ Uber die cytochemic der Polyphos-
phate bei Aspergillus oryzae. Acta Histochem., 13, 165–171.
K. H. Jost (1962). Die Structur eines sauren Natrium-Polyphosphates. Acta Crystallogr., 15, 951–955.
K. H. Jost (1968). Die Structur des Polyphosphates (Na 3 H(PO 3 ) 4 ) x . Acta Crystallogr., B24, 992–996.
K. H. Jost and H. J. Schulze (1969). Zur Phasentransformation des Kaliumpolyphosphates (KPO 3 ) x .
Acta Crystallogr., B25, 1110–1118.
F. Jungnickel (1973). Signiﬁcance of repressible polyphosphate phosphohydrolases in yeast and
higher plants. In Proceedings of Reaction Mechanisms and Control Properties of Phosphotrans-
ferases, Joint Biochemical Symposium USSR–DDR, Renhardsbrunnm Akademie-Verlag, Berlin,
pp. 87–91.
H. Kaltwasser (1962). Die Rolle der Polyphosphate im Phosphatstoffwechsel eines Knalegasbak-
terium (Hydrogenemonas Stamm 20). Arch. Mikrobiol., 41, 286–306.
H. Kaltwasser and H. G. Schlegel (1959). Nachweis und quantitative Bestimmung der Polyphosphate
wasserstoff-oxydierenden Bakterien. Arch. Mikrobiol., 34, 76–92.
H. Kaltwasser, G. Vogt and N. C. Schlegel (1962). Polyphosphatsynthese w¨ahrend der Nitrat-Atmung
von Micrococcus denitriﬁcans Stamm 11. Arch. Microbiol., 44, 259–267.
R. Kanai and W. Simonis (1968). Einbau von 32 P in Verschiedcne Phosphatfraktionen besonders
polyphosphate bei einzelligen Gr¨undalgen (Ankislrodesmus braunii) im Licht und im Dunkeln.
Arch. Mikrobiol., 62, 56–69.
R. Kanai, S. Miyachi and S. Miyachi (1963). Light-induced formation and mobilization of
‘Polyphosphate C’ in Chlorella cells. In H. Tamiya (Ed.), Microalgae and Photosynthetic
Bacteria, University of Tokyo Press, Tokyo, Japan, pp. 613–618.
O. Kandler (1957). ¨ Uber die Beziehungen zwischen Phosphataushalt und Photosynthese. Z.
Naturforsch., 12b, 271–280.
O. Kandler (1993). The early diversiﬁcation of life. In S. Bengston (Ed.), Early Life on Earth, Nobel
Symposium 84, Columbia University Press, New York, pp. 152–156.
K. Karbe and G. Jander (1942). The metaphosphates. Kolloid-Beih., 54, 1–11.
I. V. Karpichev, L. Cornivelli and G. M. Small (2002). Multiple regulatory roles of a novel
Saccharomyces cerevisiae protein, encoded by YOUL002c, in lipid and phosphate metabolism.
J. Biol. Chem., 277, 19609–19617.

241 242 243 244 245 246 247 248 249 250 251