A deep dive into the sablefish (Anoplopoma fimbria) opsin repertoire: insight into melanopsin expression, localization and function in an unlikely demersal model.

Barnes, Hayley

29 September 2022

Light regulates many biological processes through light-sensitive proteins called opsins. Opsins are involved in vision, but they are also expressed in extraretinal tissue, where their roles are far less clear. Fish have large opsin repertoires, derived from a long history of gene duplication and divergence, making them useful models to study opsin diversity and function. I introduce the deep-sea sablefish (Anoplopoma fimbria) as a model for opsin research for three main reasons: i) the availability of a draft genome and transcriptome, simplifying the characterization of this species’ opsin repertoire, ii) the proximity of the only sablefish aquaculture facility in the world, providing exclusive access to a large number of individuals at all developmental stages, iii) the observation that sablefish occupy very different light environments during the course of development, ranging from well-lit shallow waters to the aphotic zone, which provides a light environment context for opsin gene expression data. My survey of the genome showed that sablefish have 36 distinct opsin genes (7 visual and 29 non-visual), even though they spend most of their lives in the dark. The sablefish opsin sequences and repertoire are similar to those of other teleost fish. To test the hypothesis that the sablefish opsin repertoire is being expressed/transcribed during the comparatively brief period of time when this species is exposed to light (the free-swimming larval stage through to the juvenile stage), I quantified the expression of five paralogous genes from a well-studied non-visual opsin family (OPN4’s) in the brain across life stages. Data show statistically stable expression of Opn4m1 and Opn4m3 among life stages, a rough association of Opn4x1 and Opn4m2 expression with age and light environment, and little-to-no expression of Opn4x2. I localized proteins encoded by the most highly expressed class of OPN4 genes in the brain, the Opn4m genes, to the surface of the optic tectum just below a cranial ‘window’; a zone that has been shown to express dozens of opsins in zebrafish (a distant relative, with their ancestor diverging more than 230 million years ago). Thus, in some cases, expression appears to be correlated with light exposure not only temporally, but also spatially. By studying non-visual opsins in sablefish, I have challenged and broadened the current understanding of opsin evolution and function in fish and provided the foundation for future studies to test brain regions for light-sensitivity, perform opsin gene knock-outs, and explore potential light-independent processes. / Graduate / 2023-09-06

Radial glia

Sablefish

Opsin

Melanopsin

Immunohistochemistry

qPCR

Photoreceptors

Gene expression

Deep-sea fish

DEPTH AND DEVELOPMENT OF THE SONIC SYSTEM IN DEEP-SEA MACROURID FISHES ON THE CONTINENTAL SLOPE

Wrenn, Jonothan

01 January 2016

Work on sound production of deep-sea fishes has been limited to anatomy, and no sounds from identified species have been recorded on the continental slope. Here I examined the sonic muscles of six species in the family Macrouridae by depth (Coelorhincus carminatus, Nezumia bairdii, Coryphaenoides rupestris, Nezumia equalis, Coryphaenoides armatus, Coryphaenoides carapinus,). Due to increasingly limited food with depth, I hypothesized that sonic muscle development would decrease with depth. Sonic muscles were intrinsic and occurred in males and females. Swimbladder and sonic muscle dimensions increased linearly with fish size, but there were no clear differences with depth suggesting sound production remains important in deeper species.

rattails

grenadiers

sound production

deep-sea fish

macrourids

Macrouridae

sonic muscle

swim bladder

depth analysis

sexual dimorphism

Biology