Radioactive Contamination, Superfund Remediation, and Green Gentrification in San Francisco’s Hunters Point

Mankoff, Lawrie

01 January 2019

Bayview-Hunters Point, a neighborhood in southeastern San Francisco, has long been one of the most impoverished and polluted areas in the city. In an example of environmental racism, much of the African American community in San Francisco was segregated to Bayview-Hunters Point by racist housing policies and practices. This neighborhood was home to the Hunters Point Naval Shipyard (HPNS), which was widely polluted with hazardous wastes from shipyard operation as well as radioactive contamination from the Navy Radiological Defense Laboratory established on this property. The former HPNS was made a federal Superfund site in 1989 and has been in remediation by the Navy since, with the goal of eventual transfer of the land to the city of San Francisco for redevelopment into residential and commercial areas. Throughout the history of the HPNS, government agencies have obscured both radioactive contamination and the nearby disadvantaged community in pursuit of military and economic power. As a result, the forces of redevelopment have outpaced remediation in Hunters Point. In this thesis, I argue that in continuing the environmental racism marginalizes the community in Bayview-Hunters Point and working to hide the contamination at the nearby Superfund site government agencies, primarily the Navy and city government, have fostered the conditions for green gentrification to occur, which could have ill effects on both the longstanding community and new residents.

Superfund site

green gentrification

Bayview-Hunters Point

Navy

environmental justice

redevelopment

Mitochondria as a Target of Benzo[a]pyrene Toxicity in a PAH-adapted and Naive Population of the Atlantic Killifish (Fundulus Heteroclitus)

Jung, Dawoon

January 2009

<p>Polycyclic aromatic hydrocarbons (PAHs) are important contaminants that are found in increasing amounts in aquatic ecosystems. One of the sites that that is contaminated by extremely high levels of PAHs is the Atlantic Wood Industries Superfund Site on the Elizabeth River, VA. The Atlantic killifish (<italic>Fundulus heteroclitus</italic>) from this site exhibit increased levels of antioxidants, increased sensitivity to hypoxia, and increased expression of enzymes involved in glycolytic metabolism, suggesting that exposure to PAHs in the environment may induce changes in mitochondrial function and energy metabolism. Normal mitochondrial activity is crucial to an organism's survival. Therefore, gaining a better understanding of how mitochondria are affected by environmental contaminants such as PAHs is a pressing research objective. As a first step in understanding changes in cellular bioenergetics of aquatic organisms in response to PAHs, this research focused on the effect of benzo[a]pyrene (BaP), a representative PAH, on mitochondria the killifish model and on comparison of the mitochondria of the PAH-adapted killifish from the Elizabeth River Superfund Site to reference site fish. In order to assess the extent of mitochondrial DNA damage in the killifish, a PCR-based assay (LA-QPCR) for nuclear and mitochondrial DNA (nDNA, mtDNA) damage was adapted to this model and validated in with UV exposure and BaP exposure studies, as well as with <italic>ex situ</italic> study examining DNA damage in killifish inhabiting the Elizabeth River Superfund site. With the newly adapted LA-QPCR, mtDNA and nDNA damage in the killifish from the Elizabeth River Superfund site and from a reference site (King's Creek, VA) that were treated with BaP were examined. Similar increases in mitochondrial and nuclear DNA damage were observed in King's Creek fish treated with BaP. Killifish from the Elizabeth River showed high levels of basal nDNA and mtDNA damage compared to fish from the reference site, but the level of damage induced due to BaP treatment was much lower in Elizabeth River killifish. Laboratory-reared offspring from both populations showed increased BaP-induced damage in mtDNA, relative to nDNA. Similar to the adult experiment, the Elizabeth River larvae had higher levels of basal DNA damage than those from the reference site, but were less impacted by BaP exposure. Results suggest that BaP exposure can have important energetic consequences and that multi-generational exposure in the wild may lead to adaptation that dampens DNA damage arising from BaP exposure. Since the toxic effects of many PAHs are the result of bioactivation by cytochrome P4501A (CYP1A), the existence of enzymes that can potentially metabolize PAHs in mitochondria was verified. Using Western blot, protein similar in size to microsomal CYP1A was identified with monoclonal antibody against scup CYP1A in the mitochondrial fraction from adult male killifish livers. The size of the protein in the mitochondria was the similar to that of microsomal CYP1A. Fish dosed with BaP had increased EROD activity in the liver mitochondrial fraction compared to controls. In killifish larvae dosed with BaP and benzo[k]fluoranthene (BkF), CYP1A protein levels as well as enzyme activity were elevated. However, fish from the Elizabeth River Superfund site showed recalcitrant mitochondrial CYP1A protein levels and enzyme activity in a similar manner to microsomal CYP1A. Finally, the hypothesis that energy metabolism of BaP-treated fish may be different from the control group and that killifish from the Elizabeth River Superfund site may also have altered energy metabolism compared to reference site fish was tested. Respiration of killifish embryos treated with BaP from both populations was measured. Compared to the King's Creek control fish, all other treatment groups showed decrease in oxygen consumption, indicating lower respiration rate. However, when activities of key enzymes involved in glycolysis (PK) and anaerobic metabolism (LDH) in adult killifish liver and muscle were measured, no differences in the enzyme activities were observed in BaP-treated group compared to the control group. Moreover, metabolomic analysis on BaP treated King's Creek and Elizabeth River killifish showed no difference in the profile in all four treatment groups. The findings in this thesis contribute to the understanding of how BaP, a common environmental pollutant in the aquatic ecosystem, targets the mitochondria in fish model. Nevertheless, deeper examination of how BaP may impact mitochondrial function in killifish and potentially influence adaptation of killifish at a highly contaminated site is necessary. Further studies will elucidate whether such impacts can potentially affect the energy budget and organism level fitness in populations in the wild.</p> / Dissertation

Environmental Sciences

Health Sciences, Toxicology

Elizabeth River Superfund Site

Fundulus heteroclitus

mitochondria

polycyclic aromatic hydrocarbon

Interface behavior of water saturated limestone rock joints using hollow cylinder testing and a case history regarding mine roof stabilility : Fort Hartford Mine Superfund Site /

Cecil, Roger W.,

January 2002

Thesis (M.S)--University of Tennessee, Knoxville, 2002. / Title from title page screen (viewed on Feb. 26, 2003). Thesis advisor: Eric C. Drumm. Document formatted into pages (viii, 76 p. : ill. (some col.), maps). Vita. Includes bibliographical references.