Salve Regina Arboretum Ten Year Plan to Reach Level III Accreditation

The Salve Regina University Arboretum, located in Newport, Rhode Island is currently registered as a Level II arboretum and is intertwined with the city of Newport Arboretum. The university now has intentions to reach Level III status, as part of a ten-year plan. This plan was developed by the students of the Spring 2018 BIO 255: Conservation Biology course, instructed by Dr. Jameson Chace, Associate Professor of biology at Salve Regina University. As part of a curriculum geared towards civic engagement, the class focused on creating and optimizing strategies that can be applied to the ten-year plan. These strategies were applied to the plan categorically: a team to inventory the current tree collection; a team to develop formal educational programming; a team for informal educational programming; a team to establish goals for conservation initiative related to the arboretum; a team dedicated to research related to arboreta; and a team to develop a list of species of special interest to add to the arboretum in the coming years. In the following document, each team’s strategies for the ten-year plan are outlined. Each of the components of this plan incorporate means to fulfill the conditions to meet Level III arboretum status so that the arboretum can apply for official registration. The aforementioned teams were tasked with designing a foundation on which to work up from. This includes formal educational programming to be applied to classroom settings and informal educational programming which can be applied to community outreach-based settings. The teams that worked to strengthen the arboretum’s mission of conservation focused on researching trees that can fit into the current landscape while providing some sort of benefit to the surrounding flora/fauna. Further, many of the species of interest, such as the chestnut, hold historical value to the greater Rhode Island region. In all, the Salve Regina Arboretum must achieve a total of 500 unique species of trees and woody plants as part of its efforts to apply for Level III status. In addition to the programming and research performed so far by the student teams, the arboretum must also hire a curator to manage the programming and to oversee the arboretum as a whole. Additionally, the arboretum must continue to actively collaborate with other arboreta and should encourage scientific research. It is important to recognize that the Salve Regina University Arboretum has already been utilized in the field of microbiology and has gained some attention at the university as a resource for further research and investigation. This ten year plan, along with resources within in it, is designed to provide a list of potential guidelines and ideas that can be applied for the arboretum’s benefit and growth. The Salve Regina University arboretum is a continually growing and developing part of the greater Newport, Rhode Island community, and will continue to strengthen its mission and that of the university which oversees its success.https://digitalcommons.salve.edu/bio255_arboretum/1000/thumbnail.jp

Finishing the euchromatic sequence of the human genome

The sequence of the human genome encodes the genetic instructions for human physiology, as well as rich information about human evolution. In 2001, the International Human Genome Sequencing Consortium reported a draft sequence of the euchromatic portion of the human genome. Since then, the international collaboration has worked to convert this draft into a genome sequence with high accuracy and nearly complete coverage. Here, we report the result of this finishing process. The current genome sequence (Build 35) contains 2.85 billion nucleotides interrupted by only 341 gaps. It covers ∼99% of the euchromatic genome and is accurate to an error rate of ∼1 event per 100,000 bases. Many of the remaining euchromatic gaps are associated with segmental duplications and will require focused work with new methods. The near-complete sequence, the first for a vertebrate, greatly improves the precision of biological analyses of the human genome including studies of gene number, birth and death. Notably, the human enome seems to encode only 20,000-25,000 protein-coding genes. The genome sequence reported here should serve as a firm foundation for biomedical research in the decades ahead

Survival Patterns of Wild and Hatchery Coho Salmon in the Salish Sea

Returns of coho salmon to the Salish Sea have declined over the past three decades. Studies in the Strait of Georgia have suggested that early marine environment is a critical survival bottleneck for multiple stocks whereas forecasting efforts in Puget Sound have highlighted the variable survival among stocks within a single year. A study which investigates spatial and temporal patterns in coho marine survival is needed to explain these observations. The objectives of the current study are to determine the spatial and temporal coherence in smolt-to-adult survival for coho salmon stocks, to compare hatchery and wild smolt-to-adult survival, to determine and compare early marine survival estimates among basins, and to evaluate the contributions of marine versus freshwater survival to overall productivity of wild coho salmon populations. Marine survival estimates were derived using coded-wire tag data and adult versus smolt count data from coho salmon stocks representative of regions both inside and outside the Salish Sea. A cluster analysis was used to identify the appropriate spatial scale to consider environmental factors driving marine survival. In addition, two approaches were used to determine the contribution of survival in the marine environment to overall returns of coho salmon. The first approach examines whether early marine survival, measured from Strait of Georgia and Puget Sound trawl surveys, explains variation in total marine survival of hatchery and wild coho salmon. The second approach examines whether variation in freshwater versus marine survival best explains the cohort sizes of wild coho salmon. The results of this work identify the appropriate spatial scale to develop ecosystem indicators of marine survival and describe the importance of the marine environment in driving coho salmon returns to the Salish Sea over the last three decades

Intercellular propagated misfolding of wild-type Cu-Zn superoxide dismutase

Abstract of the a poster presented at Prion 2013, May 26-29 Banff, Alberta, Canada

A multi-city comparison of front and backyard differences in plant species diversity and nitrogen cycling in residential landscapes

We hypothesize that lower public visibility of residential backyards reduces households’ desire for social conformity, which alters residential land management and produces differences in ecological composition and function between front and backyards. Using lawn vegetation plots (7 cities) and soil cores (6 cities), we examine plant species richness and evenness and nitrogen cycling of lawns in Boston, Baltimore, Miami, Minneapolis-St. Paul, Phoenix, Los Angeles (LA), and Salt Lake City (SLC). Seven soil nitrogen measures were compared because different irrigation and fertilization practices may vary between front and backyards, which may alter nitrogen cycling in soils. In addition to lawn-only measurements, we collected and analyzed plant species richness for entire yards—cultivated (intentionally planted) and spontaneous (self-regenerating)—for front and backyards in just two cities: LA and SLC. Lawn plant species and soils were not different between front and backyards in our multi-city comparisons. However, entire-yard plant analyses in LA and SLC revealed that frontyards had significantly fewer species than backyards for both cultivated and spontaneous species. These results suggest that there is a need for a more rich and social-ecologically nuanced understanding of potential residential, household behaviors and their ecological consequences