Abstract
Ca2+-insensitive and -sensitive E1 subunits of the 2-oxoglutarate dehydrogenase complex (OGDHC) regulate tissue-specific NADH and ATP supply by mutually exclusive OGDH exons 4a and 4b. Here we show that their splicing is enforced by distant lariat branch points (dBPs) located near the 5′ splice site of the intervening intron. dBPs restrict the intron length and prevent transposon insertions, which can introduce or eliminate dBP competitors. The size restriction was imposed by a single dominant dBP in anamniotes that expanded into a conserved constellation of four dBP adenines in amniotes. The amniote clusters exhibit taxon-specific usage of individual dBPs, reflecting accessibility of their extended motifs within a stable RNA hairpin rather than U2 snRNA:dBP base-pairing. The dBP expansion took place in early terrestrial species and was followed by a uridine enrichment of large downstream polypyrimidine tracts in mammals. The dBP-protected megatracts permit reciprocal regulation of exon 4a and 4b by uridine-binding proteins, including TIA-1/TIAR and PUF60, which promote U1 and U2 snRNP recruitment to the 5′ splice site and BP, respectively, but do not significantly alter the relative dBP usage. We further show that codons for residues critically contributing to protein binding sites for Ca2+ and other divalent metals confer the exon inclusion order that mirrors the Irving-Williams affinity series, linking the evolution of auxiliary splicing motifs in exons to metallome constraints. Finally, we hypothesize that the dBP-driven selection for Ca2+-dependent ATP provision by E1 facilitated evolution of endothermy by optimizing the aerobic scope in target tissues.
Highlights
Endothermy is the maintenance of an elevated and constant body temperature (Tb) by metabolic means [1,2,3,4,5]
To test their role in exon 4a/4b regulation, we examined splicing of the human OGDH reporter in HEK293 cells individually overexpressing a battery of Y-binding proteins, including U2AF65 as a major PPT recognizer [75,76]
Isoform 4b+ was promoted by PUF60 and U2AF65 and was repressed by TIA-1 whereas PTBP1 inhibited inclusion of both mutually exclusive exons (MXEs) in mature transcripts (Figure 1F)
Summary
Endothermy is the maintenance of an elevated and constant body temperature (Tb) by metabolic means [1,2,3,4,5]. An early but most widely accepted hypothesis to elucidate selection forces that led to the emergence of ‘warmblooded’ species, known as the aerobic scope (or capacity) model [5], posited that endothermy evolved mainly through selection for high locomotor activity sustained by improved aerobic metabolism, without primarily selecting for an enhanced thermoregulation or higher Tb. The model has been supported by a functional link between resting and maximal rates of oxygen consumption (RMR and MMR) during vertebrate evolution and by fossil records that were indicative of an increased locomotion and easier ventilation, such as maxilloturbinates [2,3,4]. The hypothesis has gained further support from recent extensive phylogenetic studies [6,7], molecular mechanisms that led to selection of the most important metabolic conversion in animal history remain elusive
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