Your search keyword '"Shental N"' showing total 3 results

1. Combining 16S rRNA gene variable regions enables high-resolution microbial community profiling.

Author

Fuks G, Elgart M, Amir A, Zeisel A, Turnbaugh PJ, Soen Y, and Shental N

Subjects

Algorithms, Animals, Bacteria classification, Computer Simulation, DNA Probes genetics, DNA, Bacterial genetics, Microbiota, Phylogeny, Drosophila melanogaster microbiology, Polymerase Chain Reaction methods, RNA, Ribosomal, 16S genetics, Sequence Analysis, DNA methods

Abstract

Background: Most of our knowledge about the remarkable microbial diversity on Earth comes from sequencing the 16S rRNA gene. The use of next-generation sequencing methods has increased sample number and sequencing depth, but the read length of the most widely used sequencing platforms today is quite short, requiring the researcher to choose a subset of the gene to sequence (typically 16-33% of the total length). Thus, many bacteria may share the same amplified region, and the resolution of profiling is inherently limited. Platforms that offer ultra-long read lengths, whole genome shotgun sequencing approaches, and computational frameworks formerly suggested by us and by others all allow different ways to circumvent this problem yet suffer various shortcomings. There is a need for a simple and low-cost 16S rRNA gene-based profiling approach that harnesses the short read length to provide a much larger coverage of the gene to allow for high resolution, even in harsh conditions of low bacterial biomass and fragmented DNA., Results: This manuscript suggests Short MUltiple Regions Framework (SMURF), a method to combine sequencing results from different PCR-amplified regions to provide one coherent profiling. The de facto amplicon length is the total length of all amplified regions, thus providing much higher resolution compared to current techniques. Computationally, the method solves a convex optimization problem that allows extremely fast reconstruction and requires only moderate memory. We demonstrate the increase in resolution by in silico simulations and by profiling two mock mixtures and real-world biological samples. Reanalyzing a mock mixture from the Human Microbiome Project achieved about twofold improvement in resolution when combing two independent regions. Using a custom set of six primer pairs spanning about 1200 bp (80%) of the 16S rRNA gene, we were able to achieve ~ 100-fold improvement in resolution compared to a single region, over a mock mixture of common human gut bacterial isolates. Finally, the profiling of a Drosophila melanogaster microbiome using the set of six primer pairs provided a ~ 100-fold increase in resolution and thus enabling efficient downstream analysis., Conclusions: SMURF enables the identification of near full-length 16S rRNA gene sequences in microbial communities, having resolution superior compared to current techniques. It may be applied to standard sample preparation protocols with very little modifications. SMURF also paves the way to high-resolution profiling of low-biomass and fragmented DNA, e.g., in the case of formalin-fixed and paraffin-embedded samples, fossil-derived DNA, or DNA exposed to other degrading conditions. The approach is not restricted to combining amplicons of the 16S rRNA gene and may be applied to any set of amplicons, e.g., in multilocus sequence typing (MLST).

Published

2018

2. High-resolution microbial community reconstruction by integrating short reads from multiple 16S rRNA regions.

Author

Amir A, Zeisel A, Zuk O, Elgart M, Stern S, Shamir O, Turnbaugh PJ, Soen Y, and Shental N

Subjects

Acetobacter genetics, Acetobacter isolation & purification, Animals, Bacteria genetics, Bacteria isolation & purification, Drosophila melanogaster microbiology, Humans, Models, Statistical, Saliva microbiology, Wolbachia genetics, Wolbachia isolation & purification, Bacteria classification, High-Throughput Nucleotide Sequencing methods, Phylogeny, RNA, Ribosomal, 16S genetics, Sequence Analysis, DNA methods

Abstract

The emergence of massively parallel sequencing technology has revolutionized microbial profiling, allowing the unprecedented comparison of microbial diversity across time and space in a wide range of host-associated and environmental ecosystems. Although the high-throughput nature of such methods enables the detection of low-frequency bacteria, these advances come at the cost of sequencing read length, limiting the phylogenetic resolution possible by current methods. Here, we present a generic approach for integrating short reads from large genomic regions, thus enabling phylogenetic resolution far exceeding current methods. The approach is based on a mapping to a statistical model that is later solved as a constrained optimization problem. We demonstrate the utility of this method by analyzing human saliva and Drosophila samples, using Illumina single-end sequencing of a 750 bp amplicon of the 16S rRNA gene. Phylogenetic resolution is significantly extended while reducing the number of falsely detected bacteria, as compared with standard single-region Roche 454 Pyrosequencing. Our approach can be seamlessly applied to simultaneous sequencing of multiple genes providing a higher resolution view of the composition and activity of complex microbial communities.

Published

2013

3. The human tumor microbiome is composed of tumor type-specific intracellular bacteria

Author

Adina Weinberger, Ron Shaoul, Morgan G. I. Langille, Alexandria P. Cogdill, Giuseppe Mallel, Talia Golan, Anat Ronai, Arnon Meltser, Vancheswaran Gopalakrishnan, Christian U. Blank, Jennifer A. Wargo, Einav Yehuda-Shnaidman, Tali Dadosh, Maya Dadiani, Daniel S. Peeper, Merav Rokah, Alon Ben-Nun, Reetakshi Arora, Elinor Gigi, Aviram Nissan, Keren Levanon, Zachary A. Cooper, Tatiana Dorfman, Gavin M. Douglas, Iris Kamer, Gabriel Ologun, Ilana Livyatan, Zvi R. Cohen, Iris Barshack, Noam Shental, Elisa A. Rozeman, Nicola Baldini, Einav Nili Gal-Yam, Nancy Gavert, Shlomit Yust-Katz, Ran Kremer, Eran Segal, Ravid Straussman, Roi Weiser, Yaara Zwang, Yuval Bussi, Hagit Shapira, Tehila Atlan, Dan J. Raz, Amnon Amit, Smadar Levin-Zaidman, Bella Kaufman, Aviva Rotter-Maskowitz, Keren Bahar-Shany, Tali Siegal, Abdul Wadud Khan, Judith Sandbank, Deborah Nejman, Gili Perry, Jair Bar, Maya Lotan-Pompan, Sofia Avnet, Ofra Golani, Garold Fuks, Leore T. Geller, Sagi Harnof, Nejman D., Livyatan I., Fuks G., Gavert N., Zwang Y., Geller L.T., Rotter-Maskowitz A., Weiser R., Mallel G., Gigi E., Meltser A., Douglas G.M., Kamer I., Gopalakrishnan V., Dadosh T., Levin-Zaidman S., Avnet S., Atlan T., Cooper Z.A., Arora R., Cogdill A.P., Khan M.A.W., Ologun G., Bussi Y., Weinberger A., Lotan-Pompan M., Golani O., Perry G., Rokah M., Bahar-Shany K., Rozeman E.A., Blank C.U., Ronai A., Shaoul R., Amit A., Dorfman T., Kremer R., Cohen Z.R., Harnof S., Siegal T., Yehuda-Shnaidman E., Gal-Yam E.N., Shapira H., Baldini N., Langille M.G.I., Ben-Nun A., Kaufman B., Nissan A., Golan T., Dadiani M., Levanon K., Bar J., Yust S., Barshack I., Peeper D.S., Raz D.J., Segal E., Wargo J.A., Sandbank J., Shental N., and Straussman R.

Subjects

0301 basic medicine, Male, Colon, Macrophage, medicine.medical_treatment, Biology, 03 medical and health sciences, 0302 clinical medicine, Immune system, Breast cancer, RNA, Ribosomal, 16S, medicine, Microbiome, Breast, Lung, Multidisciplinary, Bacteria, Melanoma, Intracellular parasite, Microbiota, Ovary, Cancer, Immunotherapy, medicine.disease, 030104 developmental biology, medicine.anatomical_structure, 030220 oncology & carcinogenesis, Cancer research, Neoplasm, Female, Pancreas, Human

Abstract

Profiling tumor bacteria Bacteria are well-known residents in human tumors, but whether their presence is advantageous to the tumors or to the bacteria themselves has been unclear. As an initial step toward addressing this question, Nejman et al. produced an exhaustive catalog of the bacteria present in more than 1500 human tumors representing seven different tumor types (see the Perspective by Atreya and Turnbaugh). They found that the bacteria within tumors were localized within both cancer cells and immune cells and that the bacterial composition varied according to tumor type. Certain biologically plausible associations were identified. For example, breast cancer subtypes characterized by increased oxidative stress were enriched in bacteria that produce mycothiol, which can detoxify reactive oxygen species. Science , this issue p. 973 ; see also p. 938

Published

2020