Beyond Lux: methods for species and photoreceptor-specific quantification of ambient light for mammals.

IF 4.4 1区生物学 Q1 BIOLOGY

BMC Biology Pub Date : 2024-11-14 DOI:10.1186/s12915-024-02038-1

Richard J McDowell, Altug Didikoglu, Tom Woelders, Mazie J Gatt, Finn Moffatt, Saba Notash, Roelof A Hut, Timothy M Brown, Robert J Lucas

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引用次数: 0

Abstract

Background: Light is a key environmental regulator of physiology and behaviour. Mistimed or insufficient light disrupts circadian rhythms and is associated with impaired health and well-being across mammals. Appropriate lighting is therefore crucial for indoor housed mammals. Light is commonly measured in lux. However, this employs a spectral weighting function for human luminance and is not suitable for 'non-visual' effects of light or use across species. In humans, a photoreceptor-specific (α-opic) metrology system has been proposed as a more appropriate way of measuring light.

Results: Here we establish technology to allow this α-opic measurement approach to be readily extended across mammalian species, accounting for differences in photoreceptor types, photopigment spectral sensitivities, and eye anatomy. We develop a high-throughput method to derive spectral sensitivities for recombinantly expressed mammalian opsins and use it to establish the spectral sensitivity of melanopsin from 13 non-human mammals. We further address the need for simple measurement strategies for species-specific α-opic measures by developing an accessible online toolbox for calculating these units and validating an open hardware multichannel light sensor for 'point and click' measurement. We finally demonstrate that species-specific α-opic measurements are superior to photopic lux as predictors of physiological responses to light in mice and allow ecologically relevant comparisons of photosensitivity between species.

Conclusions: Our study presents methods for measuring light in species-specific α-opic units that are superior to the existing unit of photopic lux and holds the promise of improvements to the health and welfare of animals, scientific research reproducibility, agricultural productivity, and energy usage.

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超越 Lux：针对哺乳动物物种和感光器的环境光量化方法。

背景：光是生理和行为的关键环境调节器。光照不当或不足会扰乱昼夜节律，并与哺乳动物的健康和福祉受损有关。因此，适当的光照对室内饲养的哺乳动物至关重要。光照通常以勒克斯为单位进行测量。然而，这采用的是人类亮度的光谱加权函数，并不适合光的 "非视觉 "效应或跨物种使用。在人类中，光感受器特异性（α-opic）计量系统被认为是测量光的更合适方法：结果：我们在此建立了一种技术，使这种α-近视测量方法能够在哺乳动物物种间轻松推广，并考虑到感光器类型、感光色素光谱灵敏度和眼部解剖结构的差异。我们开发了一种高通量方法，用于推导重组表达的哺乳动物视蛋白的光谱灵敏度，并利用这种方法确定了 13 种非人类哺乳动物黑色素视蛋白的光谱灵敏度。我们还开发了一个用于计算这些单位的在线工具箱，并验证了一种用于 "点击式 "测量的开放硬件多通道光传感器，从而进一步满足了对物种特异性α视蛋白测量的简单测量策略的需求。最后，我们证明了物种特异性α-近视测量值在预测小鼠对光的生理反应方面优于光照勒克斯，并可对物种间的光敏性进行生态学相关比较：我们的研究提出了以物种特异性 α-光度单位测量光线的方法，这种方法优于现有的光度勒克斯单位，有望改善动物的健康和福利、科学研究的可重复性、农业生产力和能源使用。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

BMC Biology 生物-生物学

CiteScore

7.80

自引率

1.90%

发文量

260

审稿时长

3 months

期刊介绍： BMC Biology is a broad scope journal covering all areas of biology. Our content includes research articles, new methods and tools. BMC Biology also publishes reviews, Q&A, and commentaries.