More Like this

1. Deducing high-accuracy protein contact-maps from a triplet of coevolutionary matrices through deep residual convolutional networks

   https://doi.org/10.1371/journal.pcbi.1008865  

   Li, Yang ; Zhang, Chengxin ; Bell, Eric W. ; Zheng, Wei ; Zhou, Xiaogen ; Yu, Dong-Jun ; Zhang, Yang ( March 2021 , PLOS Computational Biology)

   Kolodny, Rachel (Ed.)

   The topology of protein folds can be specified by the inter-residue contact-maps and accurate contact-map prediction can help ab initio structure folding. We developed TripletRes to deduce protein contact-maps from discretized distance profiles by end-to-end training of deep residual neural-networks. Compared to previous approaches, the major advantage of TripletRes is in its ability to learn and directly fuse a triplet of coevolutionary matrices extracted from the whole-genome and metagenome databases and therefore minimize the information loss during the course of contact model training. TripletRes was tested on a large set of 245 non-homologous proteins from CASP 11&12 and CAMEO experiments and outperformed other top methods from CASP12 by at least 58.4% for the CASP 11&12 targets and 44.4% for the CAMEO targets in the top- L long-range contact precision. On the 31 FM targets from the latest CASP13 challenge, TripletRes achieved the highest precision (71.6%) for the top- L /5 long-range contact predictions. It was also shown that a simple re-training of the TripletRes model with more proteins can lead to further improvement with precisions comparable to state-of-the-art methods developed after CASP13. These results demonstrate a novel efficient approach to extend the power of deep convolutional networks for high-accuracy medium- and long-range protein contact-map predictions starting from primary sequences, which are critical for constructing 3D structure of proteins that lack homologous templates in the PDB library. 

   more » « less
2. Unique features of different classes of G‐protein‐coupled receptors revealed from sequence coevolutionary and structural analysis

   https://doi.org/10.1002/prot.26256  

   Do, Hung N. ; Haldane, Allan ; Levy, Ronald M. ; Miao, Yinglong ( February 2022 , Proteins: Structure, Function, and Bioinformatics)
3. Divergent coevolutionary trajectories in parent–offspring interactions and discrimination against brood parasites revealed by interspecific cross-fostering

   https://doi.org/10.1098/rsos.180189  

   Capodeanu-Nägler, Alexandra ; Ruiz de la Torre, Elena ; Eggert, Anne-Katrin ; Sakaluk, Scott K. ; Steiger, Sandra ( June 2018 , Royal Society Open Science)
4. Coevolutionary theory of hosts and parasites

   https://doi.org/10.1111/jeb.13981  

   Buckingham, Lydia J. ; Ashby, Ben ( April 2022 , Journal of Evolutionary Biology)
5. Genomic Approaches to Uncovering the Coevolutionary History of Parasitic Lice

   https://doi.org/10.3390/life12091442  

   Johnson, Kevin P. ( September 2022 , Life)

   Next-generation sequencing technologies are revolutionizing the fields of genomics, phylogenetics, and population genetics. These new genomic approaches have been extensively applied to a major group of parasites, the lice (Insecta: Phthiraptera) of birds and mammals. Two louse genomes have been assembled and annotated to date, and these have opened up new resources for the study of louse biology. Whole genome sequencing has been used to assemble large phylogenomic datasets for lice, incorporating sequences of thousands of genes. These datasets have provided highly supported trees at all taxonomic levels, ranging from relationships among the major groups of lice to those among closely related species. Such approaches have also been applied at the population scale in lice, revealing patterns of population subdivision and inbreeding. Finally, whole genome sequence datasets can also be used for additional study beyond that of the louse nuclear genome, such as in the study of mitochondrial genome fragmentation or endosymbiont function. 

   more » « less