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1. Eye development influences horn size but not patterning in horned beetles

   https://doi.org/10.1111/ede.12479  

   Sestrick, Kat; Moczek, Armin_P (May 2024, Evolution & Development)

   Abstract Understanding the origin of novel morphological traits is a long‐standing objective in evolutionary developmental biology. We explored the developmental genetic mechanisms that underpin the formation of a textbook example of evolutionary novelties, the cephalic horns of beetles. Previous work has implicated the gene regulatory networks associated with compound eye and ocellar development in horn formation and suggested that horns and compound eyes may influence each other's sizes. Therefore, we investigated the functional significance of genes central to visual system formation in the initiation, patterning, and size determination of head horns across three horned beetle species. We find that while the downregulation of canonical eye patterning genes reliably reduces or eliminates compound eye formation, it does not alter the position or shape of head horns yet does result in an increase in relative horn length. We discuss the implications of our results for our understanding of the genesis of cephalic horns in particular and evolutionary novelties in general. 

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2. Event-Based Sensing and Signal Processing in the Visual, Auditory, and Olfactory Domain: A Review

   https://doi.org/10.3389/fncir.2021.610446  

   Tayarani-Najaran, Mohammad-Hassan; Schmuker, Michael (May 2021, Frontiers in Neural Circuits)

   The nervous systems converts the physical quantities sensed by its primary receptors into trains of events that are then processed in the brain. The unmatched efficiency in information processing has long inspired engineers to seek brain-like approaches to sensing and signal processing. The key principle pursued in neuromorphic sensing is to shed the traditional approach of periodic sampling in favor of an event-driven scheme that mimicks sampling as it occurs in the nervous system, where events are preferably emitted upon the change of the sensed stimulus. In this paper we highlight the advantages and challenges of event-based sensing and signal processing in the visual, auditory and olfactory domains. We also provide a survey of the literature covering neuromorphic sensing and signal processing in all three modalities. Our aim is to facilitate research in event-based sensing and signal processing by providing a comprehensive overview of the research performed previously as well as highlighting conceptual advantages, current progress and future challenges in the field. 

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3. Hip Hop as Computational Neuroscience: How the Hood Hacked our Global Rhythmic Nervous System

   https://doi.org/10.33137/ijidi.v6i1.37127  

   Eglash, Ron (May 2022, The International Journal of Information, Diversity, & Inclusion (IJIDI))

   Long before the internet provided us with a networked digital system, music exchanges had created a global networked analog system, built of recordings, radio broadcasts, and live performance. The features that allowed some audio formations to go viral, while others failed, fall at the intersection of three domains: access, culture, and cognition. We know how the explosive growth of the hip hop recording industry addressed the access problem, and how hip hop lyrics addressed cultural needs. But why does hip hop make your ass shake? This essay proposes that hip hop artists were creating an innovation in brain-to-brain connectivity. That is to say, there are deep parts of the limbic system that had not previously been connected to linguistic centers in the combination of neural and social pathways that hip hop facilitated. This research is not an argument for using computational neuroscience to analyze hip hop. Rather, it is asking what hip hop artists accomplished as the street version of computational neuroscientists; and, how they strategically deployed Black music traditions to rewire the world’s global rhythmic nervous system for new cognitive, cultural, and political alignments and sensibilities. 

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4. Leanchoiliidae reveals the ancestral organization of the stem euarthropod brain

   Tian Lan, Yuanlong Zhao (October 2021, Current biography)

   Fossils provide insights into how organs may have diversified over geological time.1 However, diversification already accomplished early in evolution can obscure ancestral events leading to it. For example, already by the mid-Cambrian period, euarthropods had condensed brains typifying modern mandibulate lineages.2 However, the demonstration that extant euarthropods and chordates share orthologous developmental control genes defining the segmental fore-, mid-, and hindbrain suggests that those character states were present even before the onset of the Cambrian.3 Fossilized nervous systems of stem Euarthropodamight, therefore, be expected to reveal ancestral segmental organization, from which divergent arrangements emerged. Here, we demonstrate unsurpassed preservation of cerebral tissue in Kaili leanchoiliids revealing near-identical arrangements of bilaterally symmetric ganglia identified as the proto-, deuto-, and tritocerebra disposed behind an asegmental frontal domain, the prosocerebrum, from which paired nerves extend to labral ganglia flanking the stomodeum. This organization corresponds to labral connections hallmarking extant euarthropod clades4 and to predicted transformations of presegmental ganglia serving raptorial preocular appendages of Radiodonta.5 Trace nervous system in the gilled lobopodian Kerygmachela kierkegaardi6 suggests an even deeper prosocerebral ancestry. An asegmental prosocerebrum resolves its location relative to the midline asegmental sclerite of the radiodontan head, which persists in stem Euarthropoda.7 Here, data from two Kaili Leanchoilia, with additional reference to Alalcomenaeus,8,9 demonstrate that Cambrian stem Euarthropoda confirm genomic and developmental studies10–15 claiming that the most frontal domain of the euarthropod brain is a unique evolutionary module distinct from, and ancestral to, the fore-, mid-, and hindbrain. 

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5. CTCF loss has limited effects on global genome architecture in Drosophila despite critical regulatory functions

   https://doi.org/10.1038/s41467-021-21366-2  

   Kaushal, Anjali; Mohana, Giriram; Dorier, Julien; Özdemir, Isa; Omer, Arina; Cousin, Pascal; Semenova, Anastasiia; Taschner, Michael; Dergai, Oleksandr; Marzetta, Flavia; et al (December 2021, Nature Communications)

   null (Ed.)

   Abstract Vertebrate genomes are partitioned into contact domains defined by enhanced internal contact frequency and formed by two principal mechanisms: compartmentalization of transcriptionally active and inactive domains, and stalling of chromosomal loop-extruding cohesin by CTCF bound at domain boundaries. While Drosophila has widespread contact domains and CTCF, it is currently unclear whether CTCF-dependent domains exist in flies. We genetically ablate CTCF in Drosophila and examine impacts on genome folding and transcriptional regulation in the central nervous system. We find that CTCF is required to form a small fraction of all domain boundaries, while critically controlling expression patterns of certain genes and supporting nervous system function. We also find that CTCF recruits the pervasive boundary-associated factor Cp190 to CTCF-occupied boundaries and co-regulates a subset of genes near boundaries together with Cp190. These results highlight a profound difference in CTCF-requirement for genome folding in flies and vertebrates, in which a large fraction of boundaries are CTCF-dependent and suggest that CTCF has played mutable roles in genome architecture and direct gene expression control during metazoan evolution. 

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