Airframe noise prediction evaluation

The objective of this study is to evaluate the accuracy and adequacy of current airframe noise prediction methods using available airframe noise measurements from tests of a narrow body transport (DC-9) and a wide body transport (DC-10) in addition to scale model test data. General features of the airframe noise from these aircraft and models are outlined. The results of the assessment of two airframe prediction methods, Fink's and Munson's methods, against flight test data of these aircraft and scale model wind tunnel test data are presented. These methods were extensively evaluated against measured data from several configurations including clean, slat deployed, landing gear-deployed, flap deployed, and landing configurations of both DC-9 and DC-10. They were also assessed against a limited number of configurations of scale models. The evaluation was conducted in terms of overall sound pressure level (OASPL), tone corrected perceived noise level (PNLT), and one-third-octave band sound pressure level (SPL)

Rapid Adaptive Responses to Climate Change in Corals

Pivotal to projecting the fate of coral reefs is the capacity of reef-building corals to acclimatize and adapt to climate change. Transgenerational plasticity may enable some marine organisms to acclimatize over several generations and it has been hypothesized that epigenetic processes and microbial associations might facilitate adaptive responses. However, current evidence is equivocal and understanding of the underlying processes is limited. Here, we discuss prospects for observing transgenerational plasticity in corals and the mechanisms that could enable adaptive plasticity in the coral holobiont, including the potential role of epigenetics and coral-associated microbes. Well-designed and strictly controlled experiments are needed to distinguish transgenerational plasticity from other forms of plasticity, and to elucidate the underlying mechanisms and their relative importance compared with genetic adaptation

Coastal Ocean Processes : a science prospectus

CoOP (Coastal Ocean Processes) is an organization meant to study major interdisciplinary scientific problems in the coastal ocean. Its goal is "to obtain a new level of quantitative understanding of the processes that dominate the transformations, transport and fates of biologically, chemically and geologically important matter on the continental margin". Central to obtaining this understanding will be advances in observing and modeling the cross-shelf component of transport. More specific objectives are to understand 1) cross-margin exchanges, 2) air sea exchanges, 3) benthic-pelagic exchanges, 4) terrestrial inputs and 5) biological and chemical transformations within the water column. CoOP research will be carried out primarly through a series of process-oriented field studies, each involving about two years of measurements. Each of these field studies is to be initiated and defined through a community workshop. In addition to the process studies, CoOP will also involve modeling, long time series, exploratory studies, remote sensing, technological innovation, data archiving and communications. A CoOP pilot study has been approved for funding by the National Science Foundation, and funding will begin in 1992. The CoOP science effort is thus already underway.Funding was provided by the National Science Foundation under Grant No. OCE-9108993

Healthy Nebraska: Advancing Human Health and Developing Healthy Communities

Healthy Nebraska: Advancing Human Health and Developing Healthy Communities Every day, the Institute of Agriculture and Natural Resources (IANR) is putting together a wickedly complex puzzle, in which each faculty member, researcher, Extension educator, student, staff member, partner and stakeholder is a vitally important piece. As the pieces come together, we see a picture of the world in which IANR is making a meaningful difference in sustainable food, fuel, feed, and fiber production

Profiling of promoter occupancy by PPARα in human hepatoma cells via ChIP-chip analysis

The transcription factor peroxisome proliferator-activated receptor α (PPARα) is an important regulator of hepatic lipid metabolism. While PPARα is known to activate transcription of numerous genes, no comprehensive picture of PPARα binding to endogenous genes has yet been reported. To fill this gap, we performed Chromatin immunoprecipitation (ChIP)-chip in combination with transcriptional profiling on HepG2 human hepatoma cells treated with the PPARα agonist GW7647. We found that GW7647 increased PPARα binding to 4220 binding regions. GW7647-induced binding regions showed a bias around the transcription start site and most contained a predicted PPAR binding motif. Several genes known to be regulated by PPARα, such as ACOX1, SULT2A1, ACADL, CD36, IGFBP1 and G0S2, showed GW7647-induced PPARα binding to their promoter. A GW7647-induced PPARα-binding region was also assigned to SREBP-targets HMGCS1, HMGCR, FDFT1, SC4MOL, and LPIN1, expression of which was induced by GW7647, suggesting cross-talk between PPARα and SREBP signaling. Our data furthermore demonstrate interaction between PPARα and STAT transcription factors in PPARα-mediated transcriptional repression, and suggest interaction between PPARα and TBP, and PPARα and C/EBPα in PPARα-mediated transcriptional activation. Overall, our analysis leads to important new insights into the mechanisms and impact of transcriptional regulation by PPARα in human liver and highlight the importance of cross-talk with other transcription factors

Proceedings of the Thirteenth International Society of Sports Nutrition (ISSN) Conference and Expo

Meeting Abstracts: Proceedings of the Thirteenth International Society of Sports Nutrition (ISSN) Conference and Expo Clearwater Beach, FL, USA. 9-11 June 201

Biodiversity and climate change in the oceans

The chapter summarizes global biodiversity patterns in oceans, with comments on estuaries and freshwater habitats, and the influence climate change may have on these patterns. Biodiversity patterns at a global scale owe much to climate and dispersal capabilities of individual organisms. The ocean constitutes over 90% of the habitable space on the planet. Thirty per cent of extant phylogenic groups are exclusively marine, whereas only one phylum (Arachnida) is exclusively terrestrial. However, of the estimated 8.7 million species on Earth, 2.2 million are estimated to be marine with 90% yet to be described (Mora et al., 2011). The Achi Biodiversity Targets of the Convention on Biological Diversity aim to conserve 17% of land and freshwater and 10% of marine and coastal areas by 2020. Presently, approximately 12% of the land area is protected, against <1% of the world's oceans and adjacent seas, representing roughly 70% and 10% of the 2020 conservation goals set by the Achi targets. The abundance of life in oceans is extremely variable, with high species diversity and biomass on many continental shelf seas particularly the western equatorial Pacific region where coral reefs support a rich biodiversity (Tittensor et al., 2010), estimated over 1,000 species per m2. Oceans are major sources of global wealth, and ocean fisheries provide over 15% of human dietary intake of animal protein. However, they are all vulnerable to impacts of different types – commercial overexploitation of the world's fish stocks is so severe that it has been estimated that up to 13% of global fisheries have collapsed. This chapter will discuss the major climate change‐linked stressors that affect ocean biodiversity, and how these act via direct and indirect means to affect fish populations and assemblages. We will look at a range of approaches to understanding climate change responses, including empirical, physiological, behavioral, and modeling