Asynchronous evolutionary origins of Aß and BACE1.

Neurodegenerative plaques characteristic of Alzheimer's disease (AD) are composed of amyloid beta (Aß) peptide, which is proteolyzed from amyloid precursor protein (APP) by ß-secretase (beta-site APP cleaving enzyme [BACE1]) and γ-secretase. Although γ-secretase has essential functions across metazoans, no essential roles have been identified for BACE1 or Aß. Because their only known function results in a disease phenotype, we sought to understand these components from an evolutionary perspective. We show that APP-like proteins are found throughout most animal taxa, but sequences homologous to Aß are not found outside gnathostomes and the ß cut site is only conserved within sarcopterygians. BACE1 enzymes, however, extend through basal chordates and as far as cnidaria. We then sought to determine whether BACE1 from a species that never evolved Aß could proteolyze APP substrates that include Aß. We demonstrate that BACE1 from a basal chordate is a functional ortholog that can liberate Aß from full-length human APP, indicating BACE1 activity evolved at least 360 My before Aß.

Early Animal Origin of BACE1 APP/Aß Proteolytic Function.

Alzheimer's disease is characterized, in part, by the accumulation of ß-amyloid (Aß) in the brain. Aß is produced via the proteolysis of APP by BACE1 and γ-secretase. Since BACE1 is the rate-limiting enzyme in the production of Aß, and a target for therapeutics, it is of interest to know when its proteolytic function evolved and for what purpose. Here, we take a functional evolutionary approach to show that BACE1 likely evolved from a gene duplication event near the base of the animal clade and that BACE1 APP/Aß proteolytic function evolved during early animal diversification, hundreds of millions of years before the evolution of the APP/Aß substrate. Our examination of BACE1 APP/Aß proteolytic function includes cnidarians, ctenophores, and choanoflagellates. The most basal BACE1 ortholog is found in cnidarians, while ctenophores, placozoa, and choanoflagellates have genes equally orthologous to BACE1 and BACE2. BACE1 from a cnidarian (Hydra) can cleave APP to release Aß, pushing back the date of the origin of its function to near the origin of animals. We tested more divergent BACE1/2 genes from a ctenophore (Mnemiopsis) and a choanoflagellate (Monosiga), and neither has this activity. These findings indicate that the specific proteolytic function of BACE1 evolved during the very earliest diversification of animals, most likely after a gene-duplication event.

Patterns and consequences of vertebrate Emx gene duplications.

We have cloned and analyzed two Emx genes from the lamprey Petromyzon marinus and our findings provide insight into the patterns and developmental consequences of gene duplications during early vertebrate evolution. The Emx gene family presents an excellent case for addressing these issues as gnathostome vertebrates possess two or three Emx paralogs that are highly pleiotropic, functioning in or being expressed during the development of several vertebrate synapomorphies. Lampreys are the most primitive extant vertebrates and characterization of their development and genomic organization is critical for understanding vertebrate origins. We identified two Emx genes from P. marinus and analyzed their phylogeny and their embryological expression relative to other chordate Emx genes. Our phylogenetic analysis shows that the two lamprey Emx genes group independently from the gnathostome Emx1, Emx2, and Emx3 paralogy groups. Our expression analysis shows that the two lamprey Emx genes are expressed in distinct spatial and temporal patterns that together broadly encompass the combined sites of expression of all gnathostome Emx genes. Our data support a model wherein large-scale regulatory evolution of a single Emx gene occurred after the protochordate/vertebrate divergence, but before the vertebrate radiation. Both the lamprey and gnathostome lineages then underwent independent gene duplications followed by extensive paralog subfunctionalization. Emx subfunctionalization in the telencephalon is remarkably convergent and refines our understanding of lamprey forebrain patterning. We also identify lamprey-specific sites of expression that indicate either neofunctionalization in lampreys or sites-specific nonfunctionalization of all gnathostome Emx genes. Overall, we see only very limited correlation between Emx gene duplications and the acquisition of novel expression domains.

Lamprey snail highlights conserved and novel patterning roles in vertebrate embryos.

snail genes mark presumptive mesoderm across bilaterian animals. In gnathostome vertebrates, snail genes are a multimember family that are also markers of premigratory neural crest (pnc) and some postmigratory neural crest derivatives in the pharyngeal arches. Previous studies of nonvertebrate chordates indicate that they have single snail genes that retain ancestral functions in mesoderm development and perhaps in specification of a pnc-like cell population. Lampreys are the most basal extant vertebrates, with well-defined developmental morphology. Here, we identify a single snail gene from the lamprey Petromyzon marinus that is the phylogenetic outgroup of all gnathostome snail genes. This single lamprey snail gene retains ancestral snail patterning domains present in nonvertebrate chordates. Lamprey snail is also expressed in tissues that are broadly equivalent to the combined sites of expression of all three gnathostome snail paralogy groups, excepting in embryonic tissues that are unique to gnathostomes. Importantly, while snail does not appear to demarcate an early neural crest population in lampreys as it does in gnathostomes, it may be involved in later neural crest development. Together, our results indicate that significant cis-regulatory innovation occurred in a single snail gene before the vertebrate radiation, and significant subfunctionalization occurred after snail gene duplications in the gnathostome lineages.

Vertical and horizontal integration of bioinformatics education: A modular, interdisciplinary approach.

Bioinformatics education for undergraduates has been approached primarily in two ways: introduction of new courses with largely bioinformatics focus or introduction of bioinformatics experiences into existing courses. For small colleges such as Kalamazoo, creation of new courses within an already resource-stretched setting has not been an option. Furthermore, we believe that a true interdisciplinary science experience would be best served by introduction of bioinformatics modules within existing courses in biology and chemistry and other complementary departments. To that end, with support from the Howard Hughes Medical Institute, we have developed over a dozen independent bioinformatics modules for our students that are incorporated into courses ranging from general chemistry and biology, advanced specialty courses, and classes in complementary disciplines such as computer science, mathematics, and physics. These activities have largely promoted active learning in our classrooms and have enhanced student understanding of course materials. Herein, we describe our program, the activities we have developed, and assessment of our endeavors in this area.

Evolution of retinoic acid receptors in chordates: insights from three lamprey species, Lampetra fluviatilis, Petromyzon marinus, and Lethenteron japonicum.

BACKGROUND: Retinoic acid (RA) signaling controls many developmental processes in chordates, from early axis specification to late organogenesis. The functions of RA are chiefly mediated by a subfamily of nuclear hormone receptors, the retinoic acid receptors (RARs), that act as ligand-activated transcription factors. While RARs have been extensively studied in jawed vertebrates (that is, gnathostomes) and invertebrate chordates, very little is known about the repertoire and developmental roles of RARs in cyclostomes, which are extant jawless vertebrates. Here, we present the first extensive study of cyclostome RARs focusing on three different lamprey species: the European freshwater lamprey, Lampetra fluviatilis, the sea lamprey, Petromyzon marinus, and the Japanese lamprey, Lethenteron japonicum. RESULTS: We identified four rar paralogs (rar1, rar2, rar3, and rar4) in each of the three lamprey species, and phylogenetic analyses indicate a complex evolutionary history of lamprey rar genes including the origin of rar1 and rar4 by lineage-specific duplication after the lamprey-hagfish split. We further assessed their expression patterns during embryonic development by in situ hybridization. The results show that lamprey rar genes are generally characterized by dynamic and highly specific expression domains in different embryonic tissues. In particular, lamprey rar genes exhibit combinatorial expression domains in the anterior central nervous system (CNS) and the pharyngeal region. CONCLUSIONS: Our results indicate that the genome of lampreys encodes at least four rar genes and suggest that the lamprey rar complement arose from vertebrate-specific whole genome duplications followed by a lamprey-specific duplication event. Moreover, we describe a combinatorial code of lamprey rar expression in both anterior CNS and pharynx resulting from dynamic and highly specific expression patterns during embryonic development. This 'RAR code' might function in regionalization and patterning of these two tissues by differentially modulating the expression of downstream effector genes during development.

Sequencing of the sea lamprey (Petromyzon marinus) genome provides insights into vertebrate evolution.

Lampreys are representatives of an ancient vertebrate lineage that diverged from our own ∼500 million years ago. By virtue of this deeply shared ancestry, the sea lamprey (P. marinus) genome is uniquely poised to provide insight into the ancestry of vertebrate genomes and the underlying principles of vertebrate biology. Here, we present the first lamprey whole-genome sequence and assembly. We note challenges faced owing to its high content of repetitive elements and GC bases, as well as the absence of broad-scale sequence information from closely related species. Analyses of the assembly indicate that two whole-genome duplications likely occurred before the divergence of ancestral lamprey and gnathostome lineages. Moreover, the results help define key evolutionary events within vertebrate lineages, including the origin of myelin-associated proteins and the development of appendages. The lamprey genome provides an important resource for reconstructing vertebrate origins and the evolutionary events that have shaped the genomes of extant organisms.

An amphioxus LIM-homeobox gene, AmphiLim1/5, expressed early in the invaginating organizer region and later in differentiating cells of the kidney and central nervous system.

A LIM-homeobox gene, AmphiLim1/5, from the Florida amphioxus (Branchiostoma floridae) encodes a protein that phylogenetic analysis positions at the base of a clade comprising vertebrate Lim1 and Lim5. Amphioxus AmphiLim1/5 is expressed in domains that are a composite of those of vertebrate Lim1 and Lim5, which evidently underwent subfunctionalization after duplication of an ancestral protochordate Lim1/5. During amphioxus development, transcription is first detected in the ectoderm of the blastula. Then, in the gastrula, a second expression domain appears in the mesendoderm just within the dorsal lip of the blastopore, a region known to have organizer properties in amphioxus. This mesendodermal expression corresponds to Lim1 expression in the Spemann organizer of vertebrates. At least one of the functions of vertebrate Lim1 in the organizer is to control the transcription of genes involved in cell and tissue movements during gastrulation, and a comparable early function seems likely for AmphiLim1/5 during gastrular invagination of amphioxus. Later embryos and larvae of amphioxus express AmphiLim1/5 in clusters of cells, probably motoneurons, in the anterior part of the central nervous system, in the hindgut, in Hatschek's right diverticulum (a rudiment of the rostral coelom), and in the wall of the first somite on the left side (a precursor of Hatschek's nephridium). In the early larva, expression continues in neural cells, in Hatschek's nephridium, in the wall of the rostral coelom, in the epidermis of the upper lip, and in mesoderm cells near the opening of the second gill slit. The developmental expression in Hatschek's nephridium is especially interesting because it helps support the homology between this amphioxus organ and the vertebrate pronephros.