632 research outputs found
YouTube Celebrity and the Future of Online Video
In recent years, the rise of online video streaming services has become so great that traditional media, such as television, are worried about a potential eclipse in popularity and prevalence. YouTube is the largest online streaming platform, with over 1 billion users, and accounts for one-third of all internet traffic. This study analyzes YouTube’s attempt to professionalize the platform through a new service YouTube Red – taking amateurs, making them professionals and crafting them into celebrities – and what that means for the future of online video. This study looks at other scholarly works to analyze what makes a celebrity, the professionalization of celebrity and key elements to YouTube celebrity; and how that relates to recent news and trends in the YouTube community. It also examines YouTube Red’s potential impact on aspiring professional YouTube celebrities. The study found that existing YouTube celebrities are getting more recognition and are increasingly seen as professionals. However the emergence of YouTube Red highlights the paradox of the YouTube system. While YouTube celebrity may seem easier to attain it is actually no different than any other kind of celebrity
Draft Genome of Janthinobacterium sp. RA13 Isolated from Lake Washington Sediment.
Sequencing the genome of Janthinobacterium sp. RA13 from Lake Washington sediment is announced. From the genome content, a versatile life-style is predicted, but not bona fide methylotrophy. With the availability of its genomic sequence, Janthinobacterium sp. RA13 presents a prospective model for studying microbial communities in lake sediments
Draft Genome of Pseudomonas sp. Strain 11/12A, Isolated from Lake Washington Sediment.
We announce here the genome sequencing of Pseudomonas sp. strain 11/12A from Lake Washington sediment. From the genome content, a versatile lifestyle is predicted but not one of bona fide methylotrophy. With the availability of its genomic sequence, Pseudomonas sp. 11/12A presents a prospective model for studying microbial communities in lake sediments
Draft genomes of two strains of flavobacterium isolated from lake washington sediment.
We report sequencing the genomes of two new Flavobacterium strains isolated from Lake Washington sediment. From genomic contents, versatile lifestyles were predicted but not bona fide methylotrophy. With the availability of their genomic sequences, the new Flavobacterium strains present prospective models for studying microbial communities in lake sediments
Draft genome sequences of five new strains of methylophilaceae isolated from lake washington sediment.
We sequenced the genomes of five new Methylophilaceae strains isolated from Lake Washington sediment. We used the new sequences to sort these new strains into specific Methylophilaceae ecotypes, including one novel ecotype. The new genomes expand the known diversity of Methylophilaceae and provide new models for studying the ecology of methylotrophy
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Draft genome of Rosenbergiella nectarea strain 8N4T provides insights into the potential role of this species in its plant host.
Background:Rosenbergiella nectarea strain 8N4T, the type species of the genus Rosenbergiella, was isolated from Amygdalus communis (almond) floral nectar. Other strains of this species were isolated from the floral nectar of Citrus paradisi (grapefruit), Nicotiana glauca (tobacco tree) and from Asphodelus aestivus. R. nectarea strain 8N4T is a Gram-negative, oxidase-negative, facultatively anaerobic bacterium in the family Enterobacteriaceae. Results:Here we describe features of this organism, together with its genome sequence and annotation. The DNA GC content is 47.38%, the assembly size is 3,294,717 bp, and the total number of genes are 3,346. The genome discloses the possible role that this species may play in the plant. The genome contains both virulence genes, like pectin lyase and hemolysin, that may harm plant cells and genes that are predicted to produce volatile compounds that may impact the visitation rates by nectar consumers, such as pollinators and nectar thieves. Conclusions:The genome of R. nectarea strain 8N4T reveals a mutualistic interaction with the plant host and a possible effect on plant pollination and fitness
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Improved Draft Genome Sequence of Microbacterium sp. Strain LKL04, a Bacterial Endophyte Associated with Switchgrass Plants.
We report here the genome assembly and analysis of Microbacterium strain sp. LKL04, a Gram-positive bacterial endophyte isolated from switchgrass plants (Panicum virgatum) grown on a reclaimed coal-mining site. The 2.9-Mbp genome of this bacterium was assembled into a single contig encoding 2,806 protein coding genes
Draft genome sequences of gammaproteobacterial methanotrophs isolated from lake washington sediment.
The genomes of Methylosarcina lacus LW14(T) (=ATCC BAA-1047(T) = JCM 13284(T)), Methylobacter sp. strain 21/22, Methylobacter sp. strain 31/32, Methylomonas sp. strain LW13, Methylomonas sp. strain MK1, and Methylomonas sp. strain 11b were sequenced and are reported here. All the strains are obligately methanotrophic bacteria isolated from the sediment of Lake Washington
In situ accurate determination of the zero time delay between two independent ultrashort laser pulses by observing the oscillation of an atomic excited wave packet
We propose a novel method that uses the oscillation of an atomic excited wave
packet observed through a pump-probe technique to accurately determine the zero
time delay between a pair of ultrashort laser pulses. This physically-based
approach provides an easy fix for the intractable problem of synchronizing two
different femtosecond laser pulses in a practical experimental environment,
especially where an in situ time zero measurement with high accuracy is
required.Comment: 12 pages, 3 figures, accepted to Optics Letter
Draft genome sequence of Methyloferula stellata AR4, an obligate methanotroph possessing only a soluble methane monooxygenase
Methyloferula stellata AR4 is an aerobic acidophilic methanotroph, which, in contrast to most known methanotrophs but similar to Methylocella spp., possesses only a soluble methane monooxygenase. However, it differs from Methylocella spp. by its inability to grow on multicarbon substrates. Here, we report the draft genome sequence of this bacterium
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