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References
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M. A. Nesmeyanova, A. D. Dmitriev and I. S. Kulaev (1973). High-molecular polyphosphates
and polyphosphate-metabolizing enzymes during the growth of a culture of Escherichia coli (in
Russian). Microbiologiia, 42, 213–219.
M. A. Nesmeyanova, A. D. Dmitriev and I. S. Kulaev (1974a). Regulation of enzymes of phophate
matabolism and polyP level by exogenous orthophosphate in E. coli K-12. (in Russian).
Microbiologiia, 43, 227–232.
M. A. Nesmeyanova, S. A. Gonina, A. I. Severin and I. S. Kulaev (1974b). The metabolic regulation
of phosphohydrolases in Escherichia coli (in Russian). Microbiologiia, 43, 955–960.
M. A. Nesmeyanova, S. A. Gonina and I. S. Kulaev (1975a). Biosynthesis of polyP and alkaline
phosphatase in E. coli is under control of integrated regulatory genes (in Russian). Dokl. Akad.
Nauk SSSR, 224, 710–712.
M. A. Nesmeyanova, O. B. Maraeva, A. I. Severin and I. S. Kulaev (1975b). The localization of
polyphosphatase in cells of Escherichia coli with repression and derepression of biosynthesis of
this enzyme (in Russian). Dokl. Akad. Nauk SSSR, 223, 1266–1268.
M. A. Nesmeyanova, O. B. Maraeva, A. I. Severin, E. I. Zaichkin and I. S. Kulaev (1976). The
action of detergents and proteolytic enzymes on membrane bound polyphosphohydrolases in cells
of Eschcrichia coli with repressed and de-repressed biosynthesis of these enzymes. Biokhimiya
(Moscow), 41, 1256–1262.
C. Neuherg and H. Fischer (1938). Enzymic splitting of triphosphoric acid. II. Hydrolysis by
means of an enzyme found in Aspergillus niger and yeast. Analytical reactions of triphosphate.
Enzymologia, 2, 241–252.
K. Nicolay, W. A. Scheffers, P. M. Bruinenberg and R. Kaptein (1982). Phosphorus-31 nuclear
magnetic resonance studies of intracellular pH, phosphate compartmentation and phosphate
transport in yeast. Arch. Microbiol., 133, 83–89.
31
K. Nicolay, W. A. Scheffers, P. M. Bruinenberg and R. Kaptein (1983). In vivo P-NMR studies on
the role of the vacuole in phosphate metabolism in yeasts. Arch. Microbiol., 134, 83–89.
R. Niemeyer (1975). Poly- and methaphosphaten in hoheren pﬂanzen (Lemnaceaceae). Planta, 122,
303–305.
R. Niemeyer (1976). Cyclic condensed metaphosphates and linear polyphosphates in brown and red
algae. Arch. Microbiol., 108, 243–247.
R. Niemeyer (1999). Cyclic condensed metaphosphates in plants and the possible correlation
between inorganic polyphosphates and other compounds. In H. C. Schr¨oder and W. E. G. M¨uller
(Eds), Inorganic Polyphosphates. Biochemistry, Biology, Biotechnology, Progress in Molecular
and Subcellular Biology (Special Issue), Vol. 23, Springer-Verlag, Berlin, pp. 83–101.
R. Niemeyer and G. Richter (1969). Rapidly labelled polyphosphates and metaphosphates in the
blue–green alga Anacystis nidulans. Arch. Mikrobiol., 69, 54–59.
R. Niemeyer and G. Richter (1972). Rapidly labelled polyphosphates in Acetabularia. In: S. Bonotto,
R. Goutier, R. Kirchmann, J. R. Maisin (Eds), Biology and Radiobiology of Anucleate Systems.
11. Plant Cells, Academic Press, New York and London, pp. 225–236.
R. Niemeyer and H. Selle (1989). Inorganic condensed phosphates and inositol phosphates in plant
nuclei. Biol. Chem. Hoppe Seyler, 386, 1088.
S. Niemierko (1950). Metafosforany Galleria melonella. Acta Physiol. Pol., 1, 10–18.
S. Niemierko (1953). O meta- i polifosloranach organizmach zywych. Postepy Biochem., 1, 50–62.
S. Niemierko and W. Niemierko (1950). Metaphosphate in the excreta of Galleiia mellonella. Acta
Biol. Exp., 15, 111–120.
T. Nihei (1955). A phosphorylative process, accompanied by photochemical liberation of oxygen,

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