References:

1. Dysinger, Daniel.  1998.  Chemical, Physical, and Biological Interaction at the
Berkeley Pit, Butte, Montana. Web Page:    www.mtech.edu/research/research/1998%20Research/BerkeleyLake.htm
2.  Duaime, Ted.  Montana Bureau of Mines and Geology:  Berkeley Pit Statistics.  Web
page:  www.mbmg.mtech.edu/env-berkeley.htm
3.  Mitman, G.G. 1998.  A Proposed Biological Survey of the Berkeley Pit Lake System. 
Proceedings of the 1998 Conference of Hazardous Waste Research.  pp.16-21
4.  Mitman, Grant; Phillip, Mark, et al.  Final Report:  Pit Lake System Characterization
and Remediation for the Berkeley Pit.  1999.  Mine Waste Technology Program Activity IV, Project 8
5.  Bocioaga, Daniela.  2002.  Alternatives for Bioremediation of Acidic Berkeley Pit
Lake.  Abstract from 2002 Botany Conference:  www.2002.botanyconference.org/section8/abstracts/33.shtml
6.  Bartkjowiak, Brian.  2002.  Algal Stimulation of the Berkeley Pit Lake System. 
Abstract from 2002 Botany Conference:  www.2002.botanyconference.org/section8/abstracts/28.shtml
7.  Anderson, Steve.  1998.  In-Depth Look at Berkeley Pit Lake.  Web page
summarizing current research projects at Berkeley Pit Lake.  www.mtech.edu/research/research/1998%20Research/BerkeleyLake.htm
8.  Christensen, Tyge.  1994.  Algae a taxonomic survey.  AiO Print, Ltd., Odense, SO,
Denmark. 
9.  Kramer, U.  2001.  The use of transgenic plants in the bioremediation of soils
contaminated with trace elements.  Applications in Microbiology Biotechnology.  Vol. 55, 661-672.
10.  Assuncao, A.G.L., et al.  2001.  Elevated expression of metal transporter genes in
three accessions of the metal hyperaccumulator Thlaspi caerulescens.  Plant, Cell and Environment.  Vol. 24, 217-226
11.  Lombi, Enzo, et al.  2002.  Influence of Iron Status on Cadmium and Zinc Uptake by
Different Ecotypes of the Hyperaccumulator Thlaspi caerulescens.  Plant Physiology.  Vol. 128, 1359-
12.  Rauser, W.  2000.  The role of thiols in plants under metal stress.  Sulfur Nutrition and
Sulfur Assimilation in Higher Plants. pp. 169-183
13.  Author unknown.  Metallothioneins and Phytochelatins as Mechanisms for
Phytoremediation.  Web Page:
           www.usask.ca/agriculture/plantsci/classes/plsc416/projects_2002/kruger/plsc4163.html
14.  Oven, Matjaz.  2002.  Increase of free cysteine and citric acid in plant cells exposed
to cobalt ions.  Phytochemistry.  Vol 60, 467-474.
15.  Crist, Ray.  1988.  Interactions of Metals and Protons with Algae.  Environmental
Science and Technology.  Vol. 22, 755-760
16.  Wu, Juinn-Tzong, et al.  1998.  Role of Proline Accumulation in Response to Toxic
Copper in Chlorella sp. (Chlorophyceae) Cells.  Journal of Phycology.  Vol. 34, 113-117.
17.  Webpage:  Bioremediation using Chlamydomonas.  Sayre lab, Ohio State University.
    www.biosci.ohio-state.edu/~rsayre/BIOREM.HTM
18.  Webpage containing pictures of Butte: http://images.google.com/imgres?imgurl=miningartifacts.homestead.com/files/014a_mine.jpg&imgrefurl=http://miningartifacts.homestead.com/Minephotos.html&h=307&w=512&prev=/images%3Fq%3DButte,%2BMontana%26svnum%3D10%26hl%3Den%26lr%3D%26ie%3DUTF-8%26oe%3DUTF-8


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