University of Massachusetts Boston

About: University of Massachusetts Boston is a education organization based out in Boston, Massachusetts, United States. It is known for research contribution in the topics: Population & Health care. The organization has 6541 authors who have published 12918 publications receiving 411731 citations. The organization is also known as: UMass Boston.

Marine biodiversity and ecosystem functioning: What's known and what's next?

Abstract: Marine ecosystems are experiencing rapid and pervasive changes in biodiversity and species composition. Understanding the ecosystem consequences of these changes is critical to effectively managing these systems. Over the last several years, numerous experimental manipulations of species richness have been performed, yet existing quantitative syntheses have focused on a just a subset of processes measured in experiments and, as such, have not summarized the full data available from marine systems. Here, we present the results of a meta-analysis of 110 marine experiments from 42 studies that manipulated the species richness of organisms across a range of taxa and trophic levels and analysed the consequences for various ecosystem processes (categorised as production, consumption or biogeochemical fluxes). Our results show that, generally, mixtures of species tend to enhance levels of ecosystem function relative to the average component species in monoculture, but have no effect or a negative effect on functioning relative to the ‘highest- performing’ species. These results are largely consistent with those from other syntheses, and extend conclusions to ecological functions that are commonly measured in the marine realm (e.g. nutrient release from sediment bioturbation). For experiments that manipulated three or more levels of richness, we attempted to discern the functional form of the biodiversity–ecosystem functioning relationship. We found that, for response variables related to consumption, a power-function best described the relationship, which is also consistent with previous findings. However, we identified a linear relationship between richness and production. Combined, our results suggest that changes in the number of species will, on average, tend to alter the functioning of marine ecosystems. We outline several research frontiers that will allow us to more fully understand how, why, and when diversity may drive the functioning of marine ecosystems. Synthesis The oceans host an incredible number and variety of species. However, human activities are driving rapid changes in the marine environment. It is imperative we understand ecosystem consequences of any associated loss of species. We summarized data from 110 experiments that manipulated species diversity and evaluated resulting changes to a range of ecosystem responses. We show that losing species, on average, decreases productivity, growth, and a myriad of other processes related to how marine organisms capture and utilize resources. Finally, we suggest that the loss of species may have stronger consequences for some processes than others.

SAR applications in human settlement detection, population estimation and urban land use pattern analysis: a status report

Abstract: Over 70 percent of the population of the world's developed countries live in urbanized areas. In developing countries migration to urban areas is continuing at an increasing rate. Detection and analysis of settlement patterns, estimating population, and monitoring population migration in a timely manner are requisite to accurately assess the impact of human activities on the environment. Monitoring urban land use change patterns is among the most critical information needs for future economic development planning, natural resource allocation, and environmental and ecosystem management. Previous research has demonstrated the potential of imaging radar systems in analyzing urban, population, and settlement phenomena. However, the variability and complexity within and between urban land use morphologies present a convoluted environment for analysis. Studies of vegetation, soils, geology, hydrology, and ice and snow have all received more attention and been the subject of considerably more widespread and in-depth radar research. Nevertheless, imaging radars offer some distinct advantages and opportunities for urban-based research. With the arrival of operational space imaging SAR systems, a review of the current status of applications of radar remote sensing in urban studies should be useful for focusing the authors' attention on this important area of radar research and identification of specific problems for in-depth analysis. This paper traces the history of imaging radar research for urban, settlement, and population analysis. It presents a status report on the applications of SAR in settlement detection, population estimation, assessment of the impact of human activities on the physical environment, mapping and analyzing urban land use patterns, and interpretation of socioeconomic characteristics. The demonstrated capabilities and limitations of past and current imaging radar systems with reference to these applications are described. Potential avenues of future research are addressed.

elipsa is an early determinant of ciliogenesis that links the IFT particle to membrane-associated small GTPase Rab8

Abstract: The formation and function of cilia involves the movement of intraflagellar transport (IFT) particles underneath the ciliary membrane, along axonemal microtubules. Although this process has been studied extensively, its molecular basis remains incompletely understood. For example, it is unknown how the IFT particle interacts with transmembrane proteins. To study the IFT particle further, we examined elipsa, a locus characterized by mutations that cause particularly early ciliogenesis defects in zebrafish. We show here that elipsa encodes a coiled-coil polypeptide that localizes to cilia. Elipsa protein binds to Ift20, a component of IFT particles, and Elipsa homologue in Caenorhabditis elegans, DYF-11, translocates in sensory cilia, similarly to the IFT particle. This indicates that Elipsa is an IFT particle polypeptide. In the context of zebrafish embryogenesis, Elipsa interacts genetically with Rabaptin5, a well-studied regulator of endocytosis, which in turn interacts with Rab8, a small GTPase, known to localize to cilia. We show that Rabaptin5 binds to both Elipsa and Rab8, suggesting that these proteins provide a bridging mechanism between the IFT particle and protein complexes that assemble at the ciliary membrane.

Deconstructing the model minority myth and how it contributes to the invisible minority reality in higher education research

Abstract: A better understanding of the model minority myth of Asian American and Pacific Islanders can help move toward generating an authentic understanding of these students.

Genome-wide interrogation advances resolution of recalcitrant groups in the tree of life.

Abstract: Much progress has been achieved in disentangling evolutionary relationships among species in the tree of life, but some taxonomic groups remain difficult to resolve despite increasing availability of genome-scale data sets. Here we present a practical approach to studying ancient divergences in the face of high levels of conflict, based on explicit gene genealogy interrogation (GGI). We show its efficacy in resolving the controversial relationships within the largest freshwater fish radiation (Otophysi) based on newly generated DNA sequences for 1,051 loci from 225 species. Initial results using a suite of standard methodologies revealed conflicting phylogenetic signal, which supports ten alternative evolutionary histories among early otophysan lineages. By contrast, GGI revealed that the vast majority of gene genealogies supports a single tree topology grounded on morphology that was not obtained by previous molecular studies. We also reanalysed published data sets for exemplary groups with recalcitrant resolution to assess the power of this approach. GGI supports the notion that ctenophores are the earliest-branching animal lineage, and adds insight into relationships within clades of yeasts, birds and mammals. GGI opens up a promising avenue to account for incompatible signals in large data sets and to discern between estimation error and actual biological conflict explaining gene tree discordance. Standard phylogenetic methods produce conflicting results for several parts of the tree of life. Here, a new phylogenomic method is presented, which resolves controversial relationships within the Otophysi freshwater fish and several other recalcitrant groups.