Your search keyword '"heliorhodopsin"' showing total 7 results

1. Deep dive into the diversity and properties of rhodopsins in actinomycetes of the family Geodermatophilaceae

Author

Tarlachkov, Sergey V., Starodumova, Irina P., Boueva, Olga V., Chernyshov, Sergei V., and Evtushenko, Lyudmila I.

Published

2025

2. Cryo-EM structure of a nanobody-bound heliorhodopsin

Author

Xia, Ruixue, Sun, Mingxia, Lu, Yang, Wang, Na, Zhang, Anqi, Guo, Changyou, Xu, Zhenmei, Cai, Xuehui, and He, Yuanzheng

Published

2025

3. 巨大ウイルスから発見された光でプロトンを輸送する ヘリオロドプシン.

Author

細島頌子, 角田 聡, and 神取秀樹

Subjects

*ION transport (Biology), *PHYSIOLOGY, *BIOLOGICAL transport, *RHODOPSIN, *PROTONS

Abstract

Rhodopsins convert light into signals and energy in animals and microbes. Heliorhodopsins (HeRs), a recently discovered new rhodopsin family, are widely present in archaea, bacteria, unicellular eukaryotes, and giant viruses, however their function remains unknown. Here we report that a viral HeR from marine giant virus (V2HeR3) is a light-activated proton transporter. Three environmental viral HeRs from the same group, as well as a more distantly related HeR exhibited similar ion transport activity. We here propose a proton transporting mechanism and physiological role of HeRs. [ABSTRACT FROM AUTHOR]

Published

2024

4. Heliorhodopsin Helps Photolyase to Enhance the DNA Repair Capacity

Author

Jin-gon Shim, Shin-Gyu Cho, Se-Hwan Kim, Kimleng Chuon, Seanghun Meas, Ahreum Choi, and Kwang-Hwan Jung

Subjects

DNA repair, photolyase, microbial rhodopsin, protein-protein interaction, heliorhodopsin, evolution, Microbiology, QR1-502

Abstract

ABSTRACT Light quality is a significant factor for living organisms that have photosensory systems, such as rhodopsin, a seven alpha-helical transmembrane protein with the retinal chromophore. Here, we report, for the first time, the function of new rhodopsin, which is an inverted 7-transmembrane protein, isolated from Trichococcus flocculiformis. T. flocculiformis heliorhodopsin (TfHeR) works as a regulatory helper rhodopsin that binds with class 2 cyclobutane pyrimidine dimer (CPDII) photolyase to broaden the spectrum and upregulate DNA repair activity. We have confirmed their interaction through isothermal titration calorimetry (dissociation constant of 21.7 μM) and identified the charged residues for the interaction. Based on in vivo and in vitro experiments, we showed that the binding of heliorhodopsin with photolyase improved photolyase activity by about 3-fold to repair UV-caused DNA damage. Also, the DNA repair activity of TfHeR/T. flocculiformis photolyase (TfPHR) was observed in the presence of green light. Our results suggested that heliorhodopsin directly controls the activity of photolyase and coevolves to broaden the activity spectrum by protein-protein interaction. IMPORTANCE This study reports a function for Heliorhodopsin working as a regulatory helper rhodopsin that with CPDII photolyase to broaden the spectrum and upregulating the DNA repair activity. Our results suggested that heliorhodopsin directly controls photolyase activity and coevolves to broaden the DNA repair capacity by protein-protein interaction.

Published

2022

5. Heliorhodopsin Evolution Is Driven by Photosensory Promiscuity in Monoderms

Author

Paul-Adrian Bulzu, Vinicius Silva Kavagutti, Maria-Cecilia Chiriac, Charlotte D. Vavourakis, Keiichi Inoue, Hideki Kandori, Adrian-Stefan Andrei, and Rohit Ghai

Subjects

heliorhodopsin, rhodopsins, metagenomics, oxidative stress, Microbiology, QR1-502

Abstract

ABSTRACT Rhodopsins are light-activated proteins displaying an enormous versatility of function as cation/anion pumps or sensing environmental stimuli and are widely distributed across all domains of life. Even with wide sequence divergence and uncertain evolutionary linkages between microbial (type 1) and animal (type 2) rhodopsins, the membrane orientation of the core structural scaffold of both was presumed universal. This was recently amended through the discovery of heliorhodopsins (HeRs; type 3), that, in contrast to known rhodopsins, display an inverted membrane topology and yet retain similarities in sequence, structure, and the light-activated response. While no ion-pumping activity has been demonstrated for HeRs and multiple crystal structures are available, fundamental questions regarding their cellular and ecological function or even their taxonomic distribution remain unresolved. Here, we investigated HeR function and distribution using genomic/metagenomic data with protein domain fusions, contextual genomic information, and gene coexpression analysis with strand-specific metatranscriptomics. We bring to resolution the debated monoderm/diderm occurrence patterns and show that HeRs are restricted to monoderms. Moreover, we provide compelling evidence that HeRs are a novel type of sensory rhodopsins linked to histidine kinases and other two-component system genes across phyla. In addition, we also describe two novel putative signal-transducing domains fused to some HeRs. We posit that HeRs likely function as generalized light-dependent switches involved in the mitigation of light-induced oxidative stress and metabolic circuitry regulation. Their role as sensory rhodopsins is corroborated by their photocycle dynamics and their presence/function in monoderms is likely connected to the higher sensitivity of these organisms to light-induced damage. IMPORTANCE Heliorhodopsins are enigmatic, novel rhodopsins with a membrane orientation that is opposite to all known rhodopsins. However, their cellular and ecological functions are unknown, and even their taxonomic distribution remains a subject of debate. We provide evidence that HeRs are a novel type of sensory rhodopsins linked to histidine kinases and other two-component system genes across phyla boundaries. In support of this, we also identify two novel putative signal transducing domains in HeRs that are fused with them. We also observe linkages of HeRs to genes involved in mitigation of light-induced oxidative stress and increased carbon and nitrogen metabolism. Finally, we synthesize these findings into a framework that connects HeRs with the cellular response to light in monoderms, activating light-induced oxidative stress defenses along with carbon/nitrogen metabolic circuitries. These findings are consistent with the evolutionary, taxonomic, structural, and genomic data available so far.

Published

2021

6. Construction and Analysis of Amino Acid Substitution Matrices for Optimal Alignment of Microbial Rhodopsin Sequences.

Author

Novoseletsky, V. N., Armeev, G. A., and Shaitan, K. V.

Abstract

Pairwise alignment of amino acid sequences is the basic tool of bioinformatics, which is widely used both independently and within numerous more complex methods. The effectiveness of this tool critically depends on the scoring function used, which consists of a substitution matrix and gap penalties. In this work, amino acid substitution matrices for the superfamily of microbial rhodopsins (RHOD) were constructed and analyzed and then compared with a set of general-purpose matrices (BLOSUM, VTML, PFASUM). It was shown that all matrices allow constructing alignments of microbial rhodopsin sequences of almost the same quality, but only BLOSUM and VTML matrices and their linear combinations with RHOD matrices allow revealing homology between microbial rhodopsins and heliorhodopsin. [ABSTRACT FROM AUTHOR]

Published

2019

7. Searching Metagenomes for New Rhodopsins.

Author

Rodriguez-Valera F, Pushkarev A, Rosselli R, and Béjà O

Subjects

Metagenomics, Phylogeny, Metagenome, Rhodopsins, Microbial genetics

Abstract

Most microbial groups have not been cultivated yet, and the only way to approach the enormous diversity of rhodopsins that they contain in a sensible timeframe is through the analysis of their genomes. High-throughput sequencing technologies have allowed the release of community genomics (metagenomics) of many habitats in the photic zones of the ocean and lakes. Already the harvest is impressive and included from the first bacterial rhodopsin (proteorhodopsin) to the recent discovery of heliorhodopsin by functional metagenomics. However, the search continues using bioinformatic or biochemical routes., (© 2022. The Author(s), under exclusive license to Springer Science+Business Media, LLC, part of Springer Nature.)

Published

2022