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Jawed vertebrates have inner ears with three semicircular canals, the presence of which has been used as a key to understanding evolutionary relationships. Ostracoderms, the jawless stem gnathostomes, had only two canals and lacked the lateral canal 1 – 3 . Lampreys, which are modern cyclostomes, are generally thought to possess two semicircular canals whereas the hagfishes—which are also cyclostomes—have only a single canal, which used to be regarded as a more primitive trait 1 , 4 . However, recent molecular and developmental analyses have strongly supported the monophyly of cyclostomes 5 – 7 , which has left the evolutionary trajectory of the vertebrate inner ear unclear 8 . Here we show the differentiation of the otic vesicle of the lamprey Lethenteron camtschaticum and inshore hagfish Eptatretus burgeri . This is the first time, to our knowledge, that the development of the hagfish inner ear is reported. We found that canal development in the lamprey starts with two depressions—which is reminiscent of the early developmental pattern of the inner ear in modern gnathostomes. These cyclostome otic vesicles show a pattern of expression of regulatory genes, including OTX genes, that is comparable to that of gnathosomes. Although two depressions appear in the lamprey vesicle, they subsequently fuse to form a single canal that is similar to that of hagfishes. Complete separation of the depressions results in anterior and posterior canals in gnathostomes. The single depression of the vesicle in hagfishes thus appears to be a secondarily derived trait. Furthermore, the lateral canal in crown gnathostomes was acquired secondarily—not by de novo acquisition of an OTX expression domain, but by the evolution of a developmental program downstream of the OTX genes. The differentiation of the inner ear in the lamprey Lethenteron camtschaticum and hagfish Eptatretus burgeri sheds light on the evolution of the semicircular canals of jawed vertebrates.

The evolution of terrestrial vertebrates, starting around 385 million years ago, is an iconic moment in evolution that brings to mind images of fish transforming into four-legged animals. Here, we show that this radical change in body shape was preceded by an equally dramatic change in sensory abilities akin to transitioning from seeing over short distances in a dense fog to seeing over long distances on a clear day. Measurements of eye sockets and simulations of their evolution show that eyes nearly tripled in size just before vertebrates began living on land. Computational simulations of these animal’s visual ecology show that for viewing objects through water, the increase in eye size provided a negligible increase in performance. However, when viewing objects through air, the increase in eye size provided a large increase in performance. The jump in eye size was, therefore, unlikely to have arisen for seeing through water and instead points to an unexpected hybrid of seeing through air while still primarily inhabiting water. Our results and several anatomical innovations arising at the same time suggest lifestyle similarity to crocodiles. The consequent combination of the increase in eye size and vision through air would have conferred a 1 million-fold increase in the amount of space within which objects could be seen. The “buena vista” hypothesis that our data suggest is that seeing opportunities from afar played a role in the subsequent evolution of fully terrestrial limbs as well as the emergence of elaborated action sequences through planning circuits in the nervous system.

The adaptive immune system arose 500 million years ago in ectothermic (cold-blooded) vertebrates. Classically, the adaptive immune system has been defined by the presence of lymphocytes expressing recombination-activating gene (RAG)-dependent antigen receptors and the MHC. These features are found in all jawed vertebrates, including cartilaginous and bony fish, amphibians and reptiles and are most likely also found in the oldest class of jawed vertebrates, the extinct placoderms. However, with the discovery of an adaptive immune system in jawless fish based on an entirely different set of antigen receptors — the variable lymphocyte receptors — the divergence of T and B cells, and perhaps innate-like lymphocytes, goes back to the origin of all vertebrates. This Review explores how recent developments in comparative immunology have furthered our understanding of the origins and function of the adaptive immune system.

The discovery of a living coelacanth specimen in 1938 was remarkable, as this lineage of lobe-finned fish was thought to have become extinct 70 million years ago. The modern coelacanth looks remarkably similar to many of its ancient relatives, and its evolutionary proximity to our own fish ancestors provides a glimpse of the fish that first walked on land. Here we report the genome sequence of the African coelacanth, Latimeria chalumnae. Through a phylogenomic analysis, we conclude that the lungfish, and not the coelacanth, is the closest living relative of tetrapods. Coelacanth protein-coding genes are significantly more slowly evolving than those of tetrapods, unlike other genomic features. Analyses of changes in genes and regulatory elements during the vertebrate adaptation to land highlight genes involved in immunity, nitrogen excretion and the development of fins, tail, ear, eye, brain and olfaction. Functional assays of enhancers involved in the fin-to-limb transition and in the emergence of extra-embryonic tissues show the importance of the coelacanth genome as a blueprint for understanding tetrapod evolution.

Photoreceptor degeneration due to retinitis pigmentosa (RP) is a primary cause of inherited retinal blindness. Photoreceptor cell-replacement may hold the potential for repair in a completely degenerate retina by reinstating light sensitive cells to form connections that relay information to downstream retinal layers. This study assessed the therapeutic potential of photoreceptor progenitors derived from human embryonic and induced pluripotent stem cells (ESCs and iPSCs) using a protocol that is suitable for future clinical trials. ESCs and iPSCs were cultured in four specific stages under defined conditions, resulting in generation of a near-homogeneous population of photoreceptor-like progenitors. Following transplantation into mice with end-stage retinal degeneration, these cells differentiated into photoreceptors and formed a cell layer connected with host retinal neurons. Visual function was partially restored in treated animals, as evidenced by two visual behavioral tests. Furthermore, the magnitude of functional improvement was positively correlated with the number of engrafted cells. Similar efficacy was observed using either ESCs or iPSCs as source material. These data validate the potential of human pluripotent stem cells for photoreceptor replacement therapies aimed at photoreceptor regeneration in retinal disease.

Key Points From comparison of the eyes of lampreys and jawed vertebrates, it is clear that a 'vertebrate-style' camera eye was already present in the last common ancestor of these taxa, around 500 million years ago (Mya). Numerous features of hagfish eyes are far simpler than those of vertebrate eyes, and Lamb and colleagues' interpretation is that the eyes of extant hagfish are likely to be similar to the eyes possessed by our own ancestors, some 530 Mya. The authors suggest that this 'eye' did not exhibit image-forming capabilities, and that its function was instead non-visual (possibly circadian). Comparison of photoreceptor ultrastructure across extant taxa that diverged from our own line at progessively more distant times in the past demonstrates what appears to be a series of fine gradations in cellular characteristics. This finding is consistent with a gradual evolution of improvements in photoreceptor function between 550 and 500 Mya. Dendrograms of opsin genes indicate that three major classes of opsin (rhabdomeric, 'photoisomerase' and ciliary) were present in the bilateral ancestors of protostomes and deuterostomes, around 600 Mya. They also illuminate the major features of the subsequent evolution of visual and non-visual opsins. The development of gross eye morphology and retinal microcircuitry provide clues to the evolution of the vertebrate retina. The results are consistent with the notion that a primitive retina (similar to that of hagfish) contained ciliary photoreceptors connected directly to projection neurons, and that subsequently retinal bipolar cells evolved and became inserted between the photoreceptors and the projection neurons. By integrating these findings, Lamb and colleagues propose a scenario for a long sequence of small evolutionary steps that led (some 500 Mya) to the emergence of the vertebrate camera-style eye. The authors think that this sequence satisfies Darwin's prescription for overcoming “the difficulty of believing that a perfect and complex eye could be formed by natural selection”, and they suggest a number of explicit tests of such a scenario. Darwin saw the evolution of the vertebrate eye as one of the biggest challenges for his theory. Lamb and colleagues integrate molecular and morphological evidence across different taxa and propose a sequence of evolutionary steps through which the vertebrate eye might have emerged. Charles Darwin appreciated the conceptual difficulty in accepting that an organ as wonderful as the vertebrate eye could have evolved through natural selection. He reasoned that if appropriate gradations could be found that were useful to the animal and were inherited, then the apparent difficulty would be overcome. Here, we review a wide range of findings that capture glimpses of the gradations that appear to have occurred during eye evolution, and provide a scenario for the unseen steps that have led to the emergence of the vertebrate eye.

Retinal repair Photoreceptor loss results in irreversible blindness in many retinal diseases. Attempts to repair the damage by implanting brain or retinal stem cells into adult retina have largely failed, with no new photoreceptors produced and few signs that transplanted cells connect with retinal neurons or restore vision. Now, an experiment in mice shows that adult retina can incorporate new photoreceptor cells, provided the transplanted cells are committed rod precursors at a certain stage of development, defined by expression of transcription factor Nrl (tagged green in the cell in the centre of the cover; rhodopsin, the rod photopigment, is shown red). The study could pave the way for the generation of cells suitable for transplantation from either embryonic or adult-derived stem cells. The findings also challenge the common assumption that undifferentiated stem cells offer the best prospect for CNS repair. Photoreceptor loss causes irreversible blindness in many retinal diseases. Repair of such damage by cell transplantation is one of the most feasible types of central nervous system repair; photoreceptor degeneration initially leaves the inner retinal circuitry intact and new photoreceptors need only make single, short synaptic connections to contribute to the retinotopic map. So far, brain- and retina-derived stem cells transplanted into adult retina have shown little evidence of being able to integrate into the outer nuclear layer and differentiate into new photoreceptors 1 , 2 , 3 , 4 . Furthermore, there has been no demonstration that transplanted cells form functional synaptic connections with other neurons in the recipient retina or restore visual function. This might be because the mature mammalian retina lacks the ability to accept and incorporate stem cells or to promote photoreceptor differentiation. We hypothesized that committed progenitor or precursor cells at later ontogenetic stages might have a higher probability of success upon transplantation. Here we show that donor cells can integrate into the adult or degenerating retina if they are taken from the developing retina at a time coincident with the peak of rod genesis 5 . These transplanted cells integrate, differentiate into rod photoreceptors, form synaptic connections and improve visual function. Furthermore, we use genetically tagged post-mitotic rod precursors expressing the transcription factor Nrl (ref. 6 ) (neural retina leucine zipper) to show that successfully integrated rod photoreceptors are derived only from immature post-mitotic rod precursors and not from proliferating progenitor or stem cells. These findings define the ontogenetic stage of donor cells for successful rod photoreceptor transplantation.

Key Points Vertebrate segmentation depends on an oscillator (the segmentation clock) controlling periodic signalling activities of the Notch, WNT and fibroblast growth factor (FGF) pathways, which act on precursors of the somites in the presomitic mesoderm. Spacing of the response to the periodic signal of the clock is controlled by a system of travelling posterior gradients of FGF and WNT signalling. This system leads to the successive determination of embryonic segments along the anteroposterior axis. Although the pacemaker of the oscillator has not been fully characterized, delayed negative-feedback loops have been shown to be involved in the control of oscillations in mouse and zebrafish embryos. Notch signalling is involved in the synchronization of individual cellular oscillators, resulting in coordinated waves travelling along the presomitic mesoderm. Segmental determination occurs in the presomitic mesoderm when segmentation genes such as mesoderm posterior 2 ( MESP2 ) are activated in a striped domain in response to the clock signal. This striped domain specifies the future boundaries of the somite. Somite formation relies on a molecular oscillator, the segmentation clock, which leads to oscillatory gene expression in the presomitic mesoderm; this is converted into the periodic generation of segments in response to signalling gradients referred to as the wavefront. Recent studies provide insights into the molecular mechanisms behind this intricate developmental system. Segmentation of the paraxial mesoderm is a major event of vertebrate development that establishes the metameric patterning of the body axis. This process involves the periodic formation of sequential units, termed somites, from the presomitic mesoderm. Somite formation relies on a molecular oscillator, the segmentation clock, which controls the rhythmic activation of several signalling pathways and leads to the oscillatory expression of a subset of genes in the presomitic mesoderm. The response to the periodic signal of the clock, leading to the establishment of the segmental pre-pattern, is gated by a system of travelling signalling gradients, often referred to as the wavefront. Recent studies have advanced our understanding of the molecular mechanisms involved in the generation of oscillations and how they interact and are coordinated to activate the segmental gene expression programme.

Incongruence between different phylogenomic analyses is the main challenge faced by phylogeneticists in the genomic era. To reduce incongruence, phylogenomic studies normally adopt some data filtering approaches, such as reducing missing data or using slowly evolving genes, to improve the signal quality of data. Here, we assembled a phylogenomic data set of 58 jawed vertebrate taxa and 4682 genes to investigate the backbone phylogeny of jawed vertebrates under both concatenation and coalescent-based frameworks. To evaluate the efficiency of extracting phylogenetic signals among different data filtering methods, we chose six highly intractable internodes within the backbone phylogeny of jawed vertebrates as our test questions. We found that our phylogenomic data set exhibits substantial conflicting signal among genes for these questions. Our analyses showed that non-specific data sets that are generated without bias toward specific questions are not sufficient to produce consistent results when there are several difficult nodes within a phylogeny. Moreover, phylogenetic accuracy based on non-specific data is considerably influenced by the size of data and the choice of tree inference methods. To address such incongruences, we selected genes that resolve a given internode but not the entire phylogeny. Notably, not only can this strategy yield correct relationships for the question, but it also reduces inconsistency associated with data sizes and inference methods. Our study highlights the importance of gene selection in phylogenomic analyses, suggesting that simply using a large amount of data cannot guarantee correct results. Constructing questionspecific data sets may be more powerful for resolving problematic nodes.

Whereas the gill chambers of jawless vertebrates open directly into the environment, jawed vertebrates evolved skeletal appendages that drive oxygenated water unidirectionally over the gills. A major anatomical difference between the two jawed vertebrate lineages is the presence of a single large gill cover in bony fishes versus separate covers for each gill chamber in cartilaginous fishes. Here, we find that these divergent patterns correlate with the pharyngeal arch expression of Pou3f3 orthologs. We identify a deeply conserved Pou3f3 arch enhancer present in humans through sharks but undetectable in jawless fish. Minor differences between the bony and cartilaginous fish enhancers account for their restricted versus pan-arch expression patterns. In zebrafish, mutation of Pou3f3 or the conserved enhancer disrupts gill cover formation, whereas ectopic pan-arch Pou3f3b expression generates ectopic skeletal elements resembling the multimeric covers of cartilaginous fishes. Emergence of this Pou3f3 arch enhancer >430 Mya and subsequent modifications may thus have contributed to the acquisition and diversification of gill covers and respiratory strategies during gnathostome evolution.