@article {1677, title = {The truth about scats and dogs: Next-generation sequencing and spatial capture{\textendash}recapture models offer opportunities for conservation monitoring of an endangered social canid [Next Gen Genomics Facility (INT)].}, journal = {Biological Conservation}, volume = {256}, year = {2021}, pages = {109028}, abstract = {

Obtaining accurate population counts of endangered species is central to conservation biology, with implications for gaining ecological insights, informing management strategies, and judicial use of conservation funds. Despite decades of progress in methodological developments in the realm of population ecology, reliable density estimates are unavailable for many species of conservation concern. The dhole (Asiatic wild dog Cuon alpinus) is one such endangered large carnivore found in the tropical forests of south and southeast Asia. Here, we (i) develop next-generation sequencing resources to identify individual dholes from genetic samples, (ii) apply these methods to identify individuals in the wild, from scat (fecal) samples collected through systematic field surveys and (iii) generate reliable estimates of dhole densities in Wayanad Wildlife Sanctuary (Western Ghats, India) using Spatial Capture{\textendash}Recapture {\textquoteleft}SCR{\textquoteright} models. We estimate dhole densities to be 12{\textendash}14.2 individuals/100 sq. km based on a set of SCR models, with \ 50 individuals within Wayanad{\textquoteright}s administrative boundary. Our study presents a methodological improvement in generating population estimates of an important apex predator while also offering ecologically informative insights on a species in dire need of science-based management efforts. Replicating this study across connected reserves and over time can serve as a unified framework for understanding population dynamics, population structures, landscape connectivity and metapopulation-level conservation requirements. We propose that the approach presented here may be adopted as an economically and logistically feasible protocol for conservation monitoring of dholes and other ecologically important species plagued by similar issues of data-deficiency, and insufficient funding and resources.

}, keywords = {Carnivores, Conservation monitoring, Genetic markers, Non-invasive surveys, Population estimation, Single nucleotide polymorphisms, Tropics}, issn = {0006-3207}, doi = {https://doi.org/10.1016/j.biocon.2021.109028}, url = {https://www.sciencedirect.com/science/article/pii/S000632072100080X}, author = {Arjun Srivathsa and Ryan G. Rodrigues and Kok Ben Toh and Arun Zachariah and Ryan W. Taylor and Madan K. Oli and Uma Ramakrishnan} } @article {986, title = {Enhancement of the gut barrier integrity by a microbial metabolite through the Nrf2 pathway [Discovery to Innovation Accelerator]}, journal = {Nat Commun}, volume = {10}, year = {2019}, month = {2019 Jan 09}, pages = {89}, abstract = {

The importance of gut microbiota in human health and pathophysiology is undisputable. Despite the abundance of metagenomics data, the functional dynamics of gut microbiota in human health and disease remain elusive. Urolithin A (UroA), a major microbial metabolite derived from polyphenolics of berries and pomegranate fruits displays anti-inflammatory, anti-oxidative, and anti-ageing activities. Here, we show that UroA and its potent synthetic analogue (UAS03) significantly enhance gut barrier function and inhibit unwarranted inflammation. We demonstrate that UroA and UAS03 exert their barrier functions through activation of aryl hydrocarbon receptor (AhR)- nuclear factor erythroid 2-related factor 2 (Nrf2)-dependent pathways to upregulate epithelial tight junction proteins. Importantly, treatment with these compounds attenuated colitis in pre-clinical models by remedying barrier dysfunction in addition to anti-inflammatory activities. Cumulatively, the results highlight how microbial metabolites provide two-pronged beneficial activities at gut epithelium by enhancing barrier functions and reducing inflammation to protect from colonic diseases.

}, issn = {2041-1723}, doi = {10.1038/s41467-018-07859-7}, author = {Singh, Rajbir and Chandrashekharappa, Sandeep and Bodduluri, Sobha R and Baby, Becca V and Hegde, Bindu and Kotla, Niranjan G and Hiwale, Ankita A and Saiyed, Taslimarif and Patel, Paresh and Vijay-Kumar, Matam and Langille, Morgan G I and Douglas, Gavin M and Cheng, Xi and Rouchka, Eric C and Waigel, Sabine J and Dryden, Gerald W and Alatassi, Houda and Zhang, Huang-Ge and Haribabu, Bodduluri and Vemula, Praveen K and Jala, Venkatakrishna R} } @article {510, title = {Sirtuin 1 regulates cardiac electrical activity by deacetylating the cardiac sodium channel.}, journal = {Nat Med}, year = {2017}, month = {2017 Feb 13}, abstract = {

The voltage-gated cardiac Na(+) channel (Nav1.5), encoded by the SCN5A gene, conducts the inward depolarizing cardiac Na(+) current (INa) and is vital for normal cardiac electrical activity. Inherited loss-of-function mutations in SCN5A lead to defects in the generation and conduction of the cardiac electrical impulse and are associated with various arrhythmia phenotypes. Here we show that sirtuin 1 deacetylase (Sirt1) deacetylates Nav1.5 at lysine 1479 (K1479) and stimulates INa via lysine-deacetylation-mediated trafficking of Nav1.5 to the plasma membrane. Cardiac Sirt1 deficiency in mice induces hyperacetylation of K1479 in Nav1.5, decreases expression of Nav1.5 on the cardiomyocyte membrane, reduces INa and leads to cardiac conduction abnormalities and premature death owing to arrhythmia. The arrhythmic phenotype of cardiac-Sirt1-deficient mice recapitulated human cardiac arrhythmias resulting from loss of function of Nav1.5. Increased Sirt1 activity or expression results in decreased lysine acetylation of Nav1.5, which promotes the trafficking of Nav1.5 to the plasma membrane and stimulation of INa. As compared to wild-type Nav1.5, Nav1.5 with K1479 mutated to a nonacetylatable residue increases peak INa and is not regulated by Sirt1, whereas Nav1.5 with K1479 mutated to mimic acetylation decreases INa. Nav1.5 is hyperacetylated on K1479 in the hearts of patients with cardiomyopathy and clinical conduction disease. Thus, Sirt1, by deacetylating Nav1.5, plays an essential part in the regulation of INa and cardiac electrical activity.

}, issn = {1546-170X}, doi = {10.1038/nm.4284}, author = {Vikram, Ajit and Lewarchik, Christopher M and Yoon, Jin-Young and Naqvi, Asma and Kumar, Santosh and Morgan, Gina M and Jacobs, Julia S and Li, Qiuxia and Kim, Young-Rae and Kassan, Modar and Liu, Jing and Gabani, Mohanad and Kumar, Ajay and Mehdi, Haider and Zhu, Xiaodong and Guan, Xiaoqun and Kutschke, William and Zhang, Xiaoming and Boudreau, Ryan L and Dai, Shengchuan and Matasic, Daniel S and Jung, Saet-Byel and Margulies, Kenneth B and Kumar, Vikas* and Bachschmid, Markus M and London, Barry and Irani, Kaikobad} } @article {482, title = {A protein complex network of Drosophila melanogaster. [Drosophila facility]}, journal = {Cell}, volume = {147}, year = {2011}, month = {2011 Oct 28}, pages = {690-703}, abstract = {

Determining the composition of protein complexes is an essential step toward understanding the cell as an integrated system. Using coaffinity purification coupled to mass spectrometry analysis, we examined protein associations involving nearly 5,000 individual, FLAG-HA epitope-tagged Drosophila proteins. Stringent analysis of these data, based on a statistical framework designed to define individual protein-protein interactions, led to the generation of a Drosophila protein interaction map (DPiM) encompassing 556 protein complexes. The high quality of the DPiM and its usefulness as a paradigm for metazoan proteomes are apparent from the recovery of many known complexes, significant enrichment for shared functional attributes, and validation in human cells. The DPiM defines potential novel members for several important protein complexes and assigns functional links to 586 protein-coding genes lacking previous experimental annotation. The DPiM represents, to our knowledge, the largest metazoan protein complex map and provides a valuable resource for analysis of protein complex evolution.

}, keywords = {Animals, Drosophila melanogaster, Drosophila Proteins, Proteasome Endopeptidase Complex, Protein Interaction Mapping, Proteomics, SNARE Proteins}, issn = {1097-4172}, doi = {10.1016/j.cell.2011.08.047}, author = {Guruharsha, K G and Rual, Jean-Fran{\c c}ois and Zhai, Bo and Mintseris, Julian and Vaidya, Pujita and Vaidya, Namita and Beekman, Chapman and Wong, Christina and Rhee, David Y and Cenaj, Odise and McKillip, Emily and Shah, Saumini and Stapleton, Mark and Wan, Kenneth H and Yu, Charles and Parsa, Bayan and Carlson, Joseph W and Chen, Xiao and Kapadia, Bhaveen and VijayRaghavan, K and Gygi, Steven P and Celniker, Susan E and Obar, Robert A and Artavanis-Tsakonas, Spyros} }