Expression of Ice-Binding Proteins in Caenorhabditis elegans Improves the Survival Rate upon Cold Shock and during Freezing

Kawamura, Masahiro; Takanashi, Chiaki; Yamauchi, Akari; Doi, Motomichi; Mio, Kazuhiro; Tsuda, Sakae; Sasaki, Y.

doi:10.1038/s41598-019-42650-8

Cited by 16 publications

(12 citation statements)

References 44 publications

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“…Thus, the proposed binding of IBPs to cellular surfaces can simultaneously explain both phenomena experimentally observed (10, 35) upon cell freezing: (i) the tolerance of cells to the cold shock under moderate cooling to 0° (possibly caused by the stabilization of cell surfaces caused by their binding to IBPs), and (ii) survival of cells upon stronger freezing (caused by the IBP-induced inhibition of the ice crystal appearance).…”

Section: Figmentioning

confidence: 73%

“…These proteins were first found in the blood of fish living in the Arctic and Antarctic waters (2–4). Mechanism of action of these proteins is far not clear (5, 6), but it is commonly believed that IBPs either decrease the freezing point of the bodily fluids by several degrees (7) (note that such a decrease of the freezing point by small molecules, like salts or alcohols, would require 300-500 times more material) or bind to ice crystals and prevent their growth, which is fatal to living tissues and cells (8–10).…”

Section: Figmentioning

confidence: 99%

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A novel view on the mechanism of biological activity of antifreeze proteins

Melnik

Glukhova

Соколова

et al. 2021

Preprint

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The adaptation of organisms to sub-zero temperatures is an intriguing problem in biology and biotechnology. The ice-binding antifreeze proteins are known to be responsible for the adaptation, but the mechanism of their action is still far from being clear. Here we show that: (i) in contrast to common belief, ice-binding proteins do not reduce the water freezing temperature and even raise the ice melting point; (ii) at sub-zero temperatures (to −30°C), ice can be formed only on ice-binding surfaces, but, for kinetic reasons, not in bulk water; (iii) living cells have some large surfaces, which can bind the antifreeze proteins. These facts allow suggesting that the task of antifreeze proteins is not to bind to the ice crystals already formed in the cell and stop their growth or rearrangement, but to bind to those cell surfaces where the ice nuclei can form, and thus to prevent ice formation completely.

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Section: Figmentioning

confidence: 73%

Section: Figmentioning

confidence: 99%

A novel view on the mechanism of biological activity of antifreeze proteins

Melnik

Glukhova

Соколова

et al. 2021

Preprint

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“…Some IBPs lack a signal peptide and may have other functions, such as anchoring cells to an ice substrate or fortifying cell walls against ice. For example, a type 1 IBP gene from a snow mold (without its signal peptide), when expressed in body wall muscle of C. elegans , was found to dramatically increase the worm’s freezing tolerance (Kuramochi et al, 2019).…”

Section: Discussionmentioning

confidence: 99%

Ice-Binding Proteins in a Chrysophycean Snow Alga: Acquisition of an Essential Gene by Horizontal Gene Transfer

Raymond¹,

Remias²

2019

Front. Microbiol.

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All ice-associated algae examined so far have genes for ice-binding proteins (IBPs), which suggest that these proteins are essential for survival in icy habitats. The most common type of IBP, type 1 IBPs (also referred to as DUF3494 IBPs), is also found in ice-associated bacteria and fungi. Previous studies have suggested that algal IBP genes were acquired by horizontal transfer from other microorganisms (probably bacteria). However, it remains unclear whether this is also the case for algae distantly related to the ones examined so far and whether microorganisms other than bacteria could be the donors. Furthermore, there is only limited evidence that these proteins are expressed at low temperature. Here, we show that Kremastochrysopsis austriaca (Chrysophyceae), an Austrian snow alga that is not closely related to any of the ice-associated algae examined so far, also produces IBPs, although their activity was weak. Sequencing the algal genome and the transcriptomes of cells grown at 1 and 15°C revealed three isoforms of a type 1 IBP. In agreement with their putative function, the three isoforms were strongly upregulated by one to two orders of magnitude at 1°C compared to 15°C. In a phylogenetic tree, the K. austriaca IBPs were distant from other algal IBPs, with the closest matches being bacterial proteins. These results suggest that the K. austriaca IBPs were derived from a gene that was acquired from a bacterium unrelated to other IBP donor bacteria and confirm by their presence in yet another alga the essential role of algal IBPs.

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“…In addition to sensing harsh touch, PVD acts as a thermosensor activated by cold temperatures 53 . Cold-shock has been previously studied as a stressor for C. elegans [53][54][55][56][57][58][59][60][61][62][63][64] . Robinson et alidentified that animals can survive short (4 hrs.)…”

Section: Acute Cold-shock Induces Neurodegeneration In Pvd Neuronmentioning

confidence: 99%

Deep learning-enabled phenotyping reveals distinct patterns of neurodegeneration induced by aging and cold-shock

Saberi-Bosari

Flores

San-Miguel

2020

Preprint

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Access to quantitative information is crucial to obtain a deeper understanding of biological systems. In addition to being low-throughput, traditional image-based analysis is mostly limited to error-prone qualitative or semi-quantitative assessment of phenotypes, particularly for complex subcellular morphologies. In this work, we apply deep learning to perform quantitative imagebased analysis of complex neurodegeneration patterns exhibited by the PVD neuron in C. elegans. We apply a Convolutional Neural Network algorithm (Mask R-CNN) to identify neurodegenerative sub-cellular protrusions that appear after cold-shock or as a result of aging. A multiparametric phenotypic profile captures the unique morphological changes induced by each perturbation. We identify that acute cold-shock-induced neurodegeneration is reversible and depends on rearing temperature, and importantly, that aging and cold-shock induce distinct neuronal beading patterns.

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Expression of Ice-Binding Proteins in Caenorhabditis elegans Improves the Survival Rate upon Cold Shock and during Freezing

Cited by 16 publications

References 44 publications

A novel view on the mechanism of biological activity of antifreeze proteins

A novel view on the mechanism of biological activity of antifreeze proteins

Ice-Binding Proteins in a Chrysophycean Snow Alga: Acquisition of an Essential Gene by Horizontal Gene Transfer

Deep learning-enabled phenotyping reveals distinct patterns of neurodegeneration induced by aging and cold-shock

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