Defensins: antimicrobial peptides of vertebrates

This review, based on my presentation at the French Academy of Sciences on May 19, 2003, describes recent progress in the study of antimicrobial peptides, mediators of innate immunity in plants and animals. The main focus is on vertebrate defensins, a family of cysteine-rich antimicrobial peptides abundantly represented in human cells and tissues.     

Sex chromosome evolution in non-mammalian vertebrates

Birds, reptiles, amphibia and fish have an enormous variety of chromosomal sex determination mechanisms that apparently do not follow any phylogenetic or taxonomic scheme. A similar picture is now emerging at the molecular level. Most genes that function downstream of the mammalian master sex-determining gene, Sry, have been found in non-mammalian vertebrates. Although the components of the machinery that determines sex seem to be conserved, their interaction and most importantly the initial trigger is not the same in all vertebrates. This variety is the consequence of the extremely dynamic process of the evolution of sex determination mechanisms and sex chromosomes, which is prone to create differences rather than uniformity.     

Molecular evolution of Bov-B LINEs in vertebrates

Since their discovery in family Bovidae (bovids), Bov-B LINEs, believed to be order-specific SINEs, have been found in all ruminants and recently also in Viperidae snakes. The distribution and the evolutionary relationships of Bov-B LINEs provide an indication of their origin and evolutionary dynamics in different species. The evolutionary origin of Bov-B LINE elements has been shown unequivocally to be in Squamata (squamates). The horizontal transfer of Bov-B LINE elements in vertebrates has been confirmed by their discontinuous phylogenetic distribution in Squamata (Serpentes and two lizard infra-orders) as well as in Ruminantia, by the high level of nucleotide identity, and by their phylogenetic relationships. The direction of horizontal transfer from Squamata to the ancestor of Ruminantia is evident from the genetic distances and discontinuous phylogenetic distribution of Bov-B LINE elements. The ancestor of Colubroidea snakes has been recognized as a possible donor of Bov-B LINE elements to Ruminantia. The timing of horizontal transfer has been estimated from the distribution of Bov-B LINE elements in Ruminantia and the fossil data of Ruminantia to be 40-50 My ago. The phylogenetic relationships of Bov-B LINE elements from the various Squamata species agrees with that of the species phylogeny, suggesting that Bov-B LINE elements have been stably maintained by vertical transmission since the origin of Squamata in the Mesozoic era.     

The evolution of feeding motor patterns in vertebrates

Despite considerable skepticism, researchers have found that the patterns of muscle activation that control feeding behaviors of lower vertebrates have been surprisingly conserved during evolution. This tendency for conservation among taxa appears in the face of marked flexibility of motor patterns within individuals. One interpretation of these apparently conflicting trends is that the most effective motor pattern for any given feeding situation is the same across substantial phylogenetic distances and morphological differences. The novel evolutionary insight provided by this research is that historical changes to motor patterns are a relatively infrequent source of trophic innovation. The spectacular diversity of feeding abilities and feeding ecology in lower vertebrates is based mostly on axes of variation, and on the innovations in the organization of muscles and the skeletal linkage systems that they drive.     

Brain insulin receptors in the evolution of vertebrates

Studies have been made on 125I-insulin binding for brain membranes from cyclostomes (the lamprey Lampetra fluviatilis), fish (pink salmon Oncorhynchus gorbuscha) and mammals (rats). The species studied differed by the level of binding (the highest in the rat and the lowest in the lamprey), which was due mainly to differences in the number of binding sites per membrane protein. Qualitative properties of the receptors in the species studied were found to be very similar. All three types of the receptors were capable of differentiating between the insulins from pig, pink salmon and lamprey, all of them binding porcine insulin more readily than the salmon one and the latter better than the insulin from the lamprey. It means that these insulins reacted not to the species specific properties of the hormone, but to biological activity of the insulin. The data obtained indicate that functionally mature insulin receptor may be found already in the brain of cyclostomes and that in the course of animal evolution from cyclostomes to mammals functional properties of this receptor did not undergo any significant changes.     

Regulatory peptides and control of food intake in non-mammalian vertebrates

The current view of the control of food intake involves a central feeding system in the hypothalamus receiving input from peripheral systems. The presence of food in the gut stimulates the release of several regulatory peptides that control gut motility and secretion. Some of these peptides also act as feedback satiety signals, responsible for termination of a meal. Among the regulatory peptides suggested as peripheral satiety signals are cholecystokinin and gastrin releasing peptide. A more long-term peripheral regulation of food intake has also been postulated and leptin has been suggested as a regulator of food intake. Several regulatory peptides mediate orexigenic or anorexigenic effects in the central feeding system. Neuropeptide Y and galanin both act centrally and stimulate the intake of food, while corticotropin releasing factor reduces food intake. At present, most information about the regulation of food intake is gained from mammalian studies and these findings are used as a base for a discussion on the current knowledge of how regulatory peptides control appetite in non-mammalian vertebrates.     

Tempo and mode of mitochondrial DNA evolution in vertebrates at the amino acid sequence level: Rapid evolution in warm-blooded vertebrates

Summary By using complete sequence data of mitochondrial DNAs, three Markov models (Day-hoff, Proportional, and Poisson models) for amino acid substitutions during evolution were applied in maximum likelihood analyses of mitochondrially encoded proteins to estimate a phylogenetic tree depicting human, cow, whale, and murids (mouse and rat), with chicken, frog, and carp as outgroups. A cow/whale clade was confirmed with a more than 99.8% confidence level by any of the three models, but the branching order among human, murids, and the cow/whale clade remained uncertain. It turned out that the Dayhoff model is by far the most appropriate model among the alternatives in approximating the amino acid substitutions of mitochondrially encoded proteins, which is consistent with a previous analysis of a more limited data set. It was shown that the substitution rate of mitochondrially encoded proteins has increased in the order of fishes, amphibians, birds, and mammals and that the rate in mammals is at least six times, probably an order of magnitude, higher than that in fishes. The higher evolutionary rate in birds and mammals than in amphibians and fishes was attributed to relaxation of selective constraints operating on proteins in warm-blooded vertebrates and to high mutation rate of bird and mammalian mitochondrial DNAs.Offprint requests to: M. Hasegawa     

Structure and evolution of the horizontal septum in vertebrates

Although the horizontal septum (HS) has been identified as playing a role in fish biomechanics and in path finding of cells during zebrafish development, its morphology is poorly known. However, it is generally regarded as an evolutionarily conserved structure. To test this idea, we applied a novel combination of techniques to analyse the HS of 35 species from all major gnathostome clades in which is visualized its collagen fibre architecture. Results show that the HS is a conserved trait only with respect to the presence of caudolateral [= epicentral] and craniolateral [= posterior oblique] collagen fibre tracts, but differs remarkably with respect to the specifications of these tracts. Our data revealed several evolutionary changes within vertebrates. In the gnathostome ancestor, the two tracts are represented by evenly distributed epicentral fibres (ECFs) and posterior oblique fibres (POFs). ECFs are condensed to distinct epicentral tendons (ECTs) in the actinopteran ancestor. POFs independently evolved to distinct posterior oblique tendons (POTs) at least two times within teleosts. Within basal teleostomes, POFs as well as ECFs or ECTs were lost two times independently. POTs were lost at least three times independently within teleosts. This view of a homoplastic HS remains stable regardless of the competing phylogenies used for analysis. Our data make problematic any generalization of biomechanical models on fish swimming that include the HS. They indicate that the pathfinding role of the HS in zebrafish may be extended to gnathostome fishes, but not to agnathans, sarcopterygian fishes and tetrapods.     

Species-specific evolution of the FcR family in endothermic vertebrates

In primates and rodents, the extended FcR family is comprised of three subsets: classical FcRs, structurally diverse cell surface receptors currently designated FCRL1-FCRL6, and intracellular proteins FCRLA and FCRLB. Using bioinformatic analysis, we revealed the FcR-like genes of the same three subsets in the genome of dog, another representative of placental mammals, and in the genome of short-tailed opossum, a representative of marsupials. In contrast, a single FcR-like gene was found in the current version of the chicken genome. This in silico finding was confirmed by the gene cloning and subsequent Southern blot hybridization. The chicken FCRL gene encodes a cell surface receptor with the extracellular region composed of four Ig-like domains of the D1-, D2-, D3-, and D4-subtypes. The gene is expressed in lymphoid and non-lymphoid tissues. Phylogenetic analysis of the mammalian and chicken genes suggested that classical FcRs, FCRLA, and FCRLB emerged after the mammalian-avian split but before the eutherian-marsupial radiation. The data obtained show that the repertoire of the classical FcRs and surface FcR-like proteins in mammalian species was shaped by an extensive recombination process, which resulted in domain shuffling and species-specific gain and loss of distinct exons or entire genes.     

Dynamic evolution of bitter taste receptor genes in vertebrates

Background  

Sensing bitter tastes is crucial for many animals because it can prevent them from ingesting harmful foods. This process is mainly mediated by the bitter taste receptors (T2R), which are largely expressed in the taste buds. Previous studies have identified some T2R gene repertoires, and marked variation in repertoire size has been noted among species. However, the mechanisms underlying the evolution of vertebrate T2R genes remain poorly understood.     

Increased activity of stress-regulating systems in Alzheimer disease

Behavioral, i.e. non-cognitive, disturbances, such as anxiety, agitation, sleep disturbances and depression occur in the majority of Alzheimer's disease (AD) patients, but their neurobiological basis is unknown. Disturbance of stress regulating systems, like the locus coeruleus, could play an important role. The locus coeruleus, the main production site of noradrenaline in the central nervous system, is involved in phenomena like attention, arousal and the response to the environment. In Alzheimer's disease, there is a marked reduction of noradrenergic neurons in the locus coeruleus. We studied the activity in the remaining locus coeruleus neurons and found an inverse relationship between the number of remaining neurons and the noradrenergic activity. This could indicate compensatory activity and loss of flexibility of this system. Clinically, the loss of flexibility could result in an impairment to focus attention and to respond to the environment. These results can be related to another stress related system, the hypothalamo-pituitary-adrenal-(HPA)axis. This means that further evaluation of both of these systems is necessary.     

Genome size evolution in vertebrates: trends and constraints

1. Studies on the genomic evolution in vertebrates have highlighted the differences existing between anamniotes and amniotes, both in quantitative and compositional terms. 2. These differences do not seem to depend on a different tendency to genic amplification, but rather on the existence of more strict and efficient constraints in amniotes. 3. Some constraints, that may be defined as "intrinsic", would act directly on the genome; among these particularly important is the chiasma frequency during meiosis. 4. Other, "extrinsic", constraints, would act indirectly through genic products or through cell morphometric parameters. 5. The genome size increase seems to depend on various mechanisms. The most wide-spread one seems to be the amplification of interspersed repetitive and non-repetitive sequences.     

Gene duplication and divergence in the early evolution of vertebrates

The duplication-degeneration-complementation model of duplicate gene preservation by subfunctionalisation is currently the best explanation for the high level of retention of duplicate genes in early vertebrate evolution. But a direct test of the applicability of this model to such ancient evolutionary events may be difficult. More likely, recent duplications in other lineages will allow us to establish general principles concerning the fate of genes of different types that are duplicated in different ways. These principles may be then extrapolated to understanding the early evolution of the vertebrates.     

Genetics, development and evolution of adaptive pigmentation in vertebrates

The study of pigmentation has played an important role in the intersection of evolution, genetics, and developmental biology. Pigmentation's utility as a visible phenotypic marker has resulted in over 100 years of intense study of coat color mutations in laboratory mice, thereby creating an impressive list of candidate genes and an understanding of the developmental mechanisms responsible for the phenotypic effects. Variation in color and pigment patterning has also served as the focus of many classic studies of naturally occurring phenotypic variation in a wide variety of vertebrates, providing some of the most compelling cases for parallel and convergent evolution. Thus, the pigmentation model system holds much promise for understanding the nature of adaptation by linking genetic changes to variation in fitness-related traits. Here, I first discuss the historical role of pigmentation in genetics, development and evolutionary biology. I then discuss recent empirically based studies in vertebrates, which rely on these historical foundations to make connections between genotype and phenotype for ecologically important pigmentation traits. These studies provide insight into the evolutionary process by uncovering the genetic basis of adaptive traits and addressing such long-standing questions in evolutionary biology as (1) are adaptive changes predominantly caused by mutations in regulatory regions or coding regions? (2) is adaptation driven by the fixation of dominant mutations? and (3) to what extent are parallel phenotypic changes caused by similar genetic changes? It is clear that coloration has much to teach us about the molecular basis of organismal diversity, adaptation and the evolutionary process.     

Molecular evolution and characterization of hepcidin gene products in vertebrates

Antimicrobial peptides (AMPs) include a diverse group of gene-encoded molecules that play a role in innate defense in many organisms. Evolutionary analyses of the AMP genes can be challenging because of gene duplication and diversification. Recently discovered, hepcidins are small, cysteine-rich antimicrobial peptides that also function as hormonal regulators of iron homeostasis. In this paper we investigated the organization, expression and molecular evolution of hepcidin. From searches of the literature and public genomic databases we collected 68 different hepcidin gene products from 51 different species, all among the vertebrates. Although some species have multiple hepcidin homologues, we suggest that each contains only one copy that functions as an iron regulator. Despite the recent report of hepcidin sequences in the pigeon (Fu, Y.M., Li, S.P., Wu, Y.F., Chang, Y.Z., 2007. Identification and expression analysis of hepcidin-like cDNAs from pigeon (Columba livia). Mol. Cell. Biochem. 305, 191-197.), searches of the chicken genomic, EST, and HTGS databases did not reveal any evidence of the presence of this gene in birds. This, along with the absence of reported avian transferrin receptor 2 and hemojuvelin sequences, suggests that iron homeostasis in birds may be regulated by an alternative mechanism.