Environmental Engineering Reference
In-Depth Information
[35]
Flores E. and Herrero A. “Assimilatory nitrogen metabolism and its regulation.” In:
The Molecular Biology of Cyanobacteria
, Bryant D. A. ed., The Netherlands: Kluwer
Academic Publishers, 1994.
[36]
Fonselius S. Oxygen and hydrogen sulphide conditions in the Baltic Sea. Mar Pollut Bull
1981; 12:187-94.
[37]
Gallon J. R. Tansley Review No. 44/Reconciling the incompatible: N
2
fixation and O
2
.
New Phytol 1992; 122:571-609.
[38]
Galloway J., Dentener F. J., Capone D. G., Boyer E. W., Howarth R. W., Seitzinger S.
P., Asner G. P., Cleveland C. C., Green P. A., Holland E. A., Karl D. M., Michaels A.
F., Porter J. H., Townsend A. R. and Vorosmarty C. J. Nitrogen cycles: past, present and
future. Biogeochemistry, 2004; 70:153-226 .
[39]
Galloway J. N. “The global nitrogen cycle.” In:
Treatise on Geochemistry
, Schesinger W.
ed., San Francisco: Elsevier Health Sciences, 2003.
[40]
Giovannoni S. J., Turner S., Olsen G. J., Barns S., Lane D. J. and Pace N. R. Evolutionary
relationships among cyanobacteria and green chloroplasts. J Bacteriol 1988; 170:3584-92.
[41]
Golubic S. and Lee S. J. Early cyanobacterial fossil record: preservation, palaeoenviron-
ments and identification. Eur J Phycol 1999; 34:339-48.
[42]
Graneli E., Wallstr om K., Larsson U., Graneli W. and Elmgren R. Nutrient limitation of
primary production in the Baltic Sea area. Ambio 1990; 19:142-51.
[43]
Gruber N. and Sarmiento J. L. Global patterns of marine nitrogen fixation and denitrifi-
cation. Global Biogeochem Cycles 1997; 11:235-66.
[44]
Gundersen K. The distribution and biological transformations of nitrogen in the Baltic
Sea. Mar Pollut Bull 1981; 12:199-205.
[45]
Hansell D. A., Bates N. R. and Olson D. B. Excess nitrate and nitrogen fixation in the
North Atlantic Ocean. Mar Chem 2004; 84:243-65.
[46]
Hartman H. Photosynthesis and the origin of life. Orig Life Evol Biosph 1998; 28:515.
[47]
Haug G. H., Pedersen T. F., Sigman D. M., Calvert S. E., Nielsen B. and Peterson L. C.
Glacial/interglacial variations in production and nitrogen fixation in the Cariaco Basin
during the last 580 kyr. Paleoceanography 1998; 13:427-32.
[48]
Hecky R. E. and Kilham P. Nutrient limitation of phytoplankton in freshwater and marine
environments: A review of recent evidence on the effects of enrichment. Limnol Oceanogr
1988; 33:796-822.
[49]
Herbert R. A. Nitrogen cycling in coastal marine ecosystems. FEMS Microbiol Rev 1999;
23:563-90.
[50]
Hill S. “Physiology of nitrogen fixation in free-living heterotrophs.” In:
Biological Nitro-
gen Fixation
, B. R. H. Stacey G. and Evans H.J. eds., New York, London: Chapman and
Hall, Inc, 1992.
[51]
Hoehler T., Bebout B. M. and Des Marais D. J. The role of microbial mats in the production
of reduced gases on the early Earth. Nature 2001; 412:324-27.
[52]
Hoover T. “Control of nitrogen fixation genes in
Klebsiella pneumoniae
.” In:
Prokaryotic
Nitrogen Fixation
, Triplett E. W. ed., Norfolk, England: Horizon Scientific Press, 2000.
[53]
Howard J. B. and Rees D. C. Structural basis of biological nitrogen fixation. Chem Rev
1996; 96:2965-82.
[54]
Howarth R. W. and Cole J. J. Molybdenum availability, nitrogen limitation, and phyto-
plankton growth in natural waters. Science 1985; 229:653-55.
