Variability in brain ganglioside content and composition of endothermic mammals, heterothermic hibernators and ectothermic fishes

Content and composition of brain gangliosides were compared among endothermic mammals, heterothermic hibernators and ectothermic fishes from habitats with extreme ambient temperatures (tropic vs. antarctic waters). In general the content of brain gangliosides in fishes is significantly lower and exhibits a greater variability than in mammals. The composition of brain gangliosides was investigated using both one- and two-dimensional High Performance Thin Layer Chromatography (HPTLC). Both techniques showed a remarkable increase in the number of individual ganglioside fractions and an additional increase of higher polar fractions in fishes as compared with mammals. The 2D-HPTLC revealed a significant decrease in the relative proportion of alkali-labile gangliosides in the course of evolution from fish to mammals. Moreover this decrease in alkali-lability is correlated with the state of thermal adaptation (antarctic fishes, 53–66%; tropical cichlid fish, 35%). These results provide additional evidence for the notion that the extremely high polarity of brain gangliosides, especially of cold-blooded vertebrates, reflects a very efficient mechanism on the molecular level to keep the neuronal membrane functional under low temperature conditions.     

Isochores and the evolutionary genomics of vertebrates

The nuclear genomes of vertebrates are mosaics of isochores, very long stretches (>300kb) of DNA that are homogeneous in base composition and are compositionally correlated with the coding sequences that they embed. Isochores can be partitioned in a small number of families that cover a range of GC levels (GC is the molar ratio of guanine+cytosine in DNA), which is narrow in cold-blooded vertebrates, but broad in warm-blooded vertebrates. This difference is essentially due to the fact that the GC-richest 10-15% of the genomes of the ancestors of mammals and birds underwent two independent compositional transitions characterized by strong increases in GC levels. The similarity of isochore patterns across mammalian orders, on the one hand, and across avian orders, on the other, indicates that these higher GC levels were then maintained, at least since the appearance of ancestors of warm-blooded vertebrates. After a brief review of our current knowledge on the organization of the vertebrate genome, evidence will be presented here in favor of the idea that the generation and maintenance of the GC-richest isochores in the genomes of warm-blooded vertebrates were due to natural selection.     

Presence of O6-methylguanine acceptor protein in the tissues of different classes of vertebrates and invertebrates

We have measured the ability of extracts of tissues from several species of mammals, birds, reptiles, amphibia and fish to demethylate adducts of O6-methylguanine in exogenous DNA by transfer of the methyl group to an acceptor protein. Our study also encompassed tissues from a smaller number of invertebrates, from arthropods, molluscs and annelids. The vertebrate tissues used were liver, brain, spleen and kidney. In the case of the invertebrates we sampled liver, neural tissue, gonads, digestive tract and hepatopancreas. There was no consistent change in the amount of acceptor activity per unit of protein or DNA going from cold-blooded to warm-blooded vertebrates. Liver invariably had the highest amount; this finding was not unexpected since metabolic processes in the liver are high, and good cellular protective mechanism important. Inter-class comparisons within the vertebrates are highly speculative, and hindered by the fact that there is little information on carcinogenesis in animals other than rodents and humans. O6-methylguanine acceptor activity was found in all the invertebrate tissues tested. The amounts were variable, 0.003-0.0051 fmol/micrograms cellular DNA, but the values fell within the range of those found in the tissues of vertebrates.     

Compositional transitions in the nuclear genomes of cold-blooded vertebrates

Summary The compositional properties of DNAs from 122 species of fishes and from 18 other coldblooded vertebrates (amphibians and reptiles) were compared with those from 10 warm-blooded vertebrates (mammals and birds) and found to be substantially different. Indeed, DNAs from cold-blooded vertebrates are characterized by much lower intermolecular compositional heterogeneities and CsCl band asymmetries, by a much wider spectrum of modal buoyant densities in CsCl, by generally lower amounts of satellites, as well as by the fact that in no case do buoyant densities reach the high values found in the GC-richest components of DNAs from warm-blooded vertebrates.In the case of fish genomes, which were more extensively studied, different orders were generally characterized by modal buoyant densities that were different in average values as well as in their ranges. In contrast, different families within any given order were more often characterized by narrow ranges of modal buoyant densities, and no difference in modal buoyant density was found within any single genus (except for the genusAphyosemion, which should be split into several genera).The compositional differences that were found among species belonging to different orders and to different families within the same order are indicative of compositional transitions, which were shown to be essentially due to directional base substitutions. These transitions were found to be independent of geological time. Moreover, the rates of directional base substitutions were found to be very variable and to reach, in some cases, extremely high values, that were even higher than those of silent substitutions in primates. The taxonomic and evolutionary implications of these findings are discussed.     

The compositional patterns of the avian genomes and their evolutionary implications

The compositional distributions of large (main-band) DNA fragments from eight birds belonging to eight different orders (including both paleognathous and neognathous species) are very broad and extremely close to each other. These findings, which are paralleled by the compositional similarity of homologous coding sequences and their codon positions, support the idea that birds are a monophyletic group.The compositional distribution of third-codon positions of genes from chicken, the only avian species for which a relatively large number of coding sequences is known, is very broad and bimodal, the minor GC-richer peak reaching 100% GC. The very high compositional heterogeneity of avian genomes is accompanied (as in the case of mammalian genomes) by a very high speciation rate compared to cold-blooded vertebrates which are characterized by genomes that are much less heterogeneous. The higher GC levels attained by avian compared to mammalian genomes might be correlated with the higher body temperature (41–43°C) of birds compared to mammals (37°C).A comparison of GC levels of coding sequences and codon positions from man and chicken revealed very close average GC levels and standard deviations. Homologous coding sequences and codon positions from man and chicken showed a surprisingly high degree of compositional similarity which was, however, higher for GC-poor than for GC-rich sequences. This indicates that GC-poor isochores of warm-blooded vertebrates reflect the composition of the isochores of the genome of the common reptilian ancestor of mammals and birds, which underwent only a small compositional change at the transition from cold- to warm-blooded vertebrates. In contrast, the GC-rich isochores of birds and mammals are the result of large compositional changes at the same evolutionary transition, where were in part different in the two classes of warm-blooded vertebrates.Correspondence to: G. Bernaadi     

Social Dispersion and Genetic Variation in Two Species of Emballonurid Bats

Saccopteryx leptura and S. bilineata are closely related, sympacric species of neotropical bats that exhibit marked differences in social organization and dispersion patterns. S. leptura is monogamous and roosts in small groups of 1 to 5 (Y = 2.6) individuals that are finely dispersed. S. bilineata is harem-polygamous and roosts in larger groups of 1 to 42 (Y = 8.1) individuals that are more coarsely dispersed. Allozyme genetic studies of individuals from Trinidad, W I. demonstrate that both species carry similar, high levels of polymorphism and heterozygosity. Although significant genetic heterogeneity was observed among geographical populations of S. leptura, there is no evidence for either species that social structuring leads to inbreeding and the loss of heterozygosity, or that it promotes the development of genetic heterogeneity among social units that could accelerate the evolutionary diversification of these taxa. These results do not support a recently proposed hypothesis that social structuring in mammals has these effects. Observed intercolony genetic heterogeneity among adult males resident in multimale groups of S. bilineata is greater than intercolony heterogeneity of adult females. This is an apparent result of female dispersal and the recruitment of males into their parental groups. These results suggest that the adult males within large colonies may be kin-related.     

Socially induced brain development in a facultatively eusocial sweat bee Megalopta genalis (Halictidae)

Changes in the relative size of brain regions are often dependent on experience and environmental stimulation, which includes an animal''s social environment. Some studies suggest that social interactions are cognitively demanding, and have examined predictions that the evolution of sociality led to the evolution of larger brains. Previous studies have compared species with different social organizations or different groups within obligately social species. Here, we report the first intraspecific study to examine how social experience shapes brain volume using a species with facultatively eusocial or solitary behaviour, the sweat bee Megalopta genalis. Serial histological sections were used to reconstruct and measure the volume of brain areas of bees behaving as social reproductives, social workers, solitary reproductives or 1-day-old bees that are undifferentiated with respect to the social phenotype. Social reproductives showed increased development of the mushroom body (an area of the insect brain associated with sensory integration and learning) relative to social workers and solitary reproductives. The gross neuroanatomy of young bees is developmentally similar to the advanced eusocial species previously studied, despite vast differences in colony size and social organization. Our results suggest that the transition from solitary to social behaviour is associated with modified brain development, and that maintaining dominance, rather than sociality per se, leads to increased mushroom body development, even in the smallest social groups possible (i.e. groups with two bees). Such results suggest that capabilities to navigate the complexities of social life may be a factor shaping brain evolution in some social insects, as for some vertebrates.     

Evolutionary diversity of reverse (R) fluorescent chromosome bands in vertebrates

Mitotic chromosomes, interphase cell nuclei, and male meiosis of 41 species representing all vertebrate classes were analyzed with distamycin A/mithramycin counterstaining. The purpose of the study was to recognize differences and common characteristics in the reverse (R) fluorescent banding patterns in the chromosomes of vertebrate species at various stages of evolution. In contrast to the warm-blooded mammals and birds, the euchromatic segments in the chromosomes of most reptiles, amphibians, and fishes contain no multiple fluorescent R-bands. This is thought to be due to the absence of the long homogeneous regions (isochores) in the DNA of the cold-blooded vertebrates. Distamycin A/mithramycin banding specifically reveals the GC-rich constitutive heterochromatin in all vertebrates. In most of the vertebrate chromosomes examined, the heterochromatic regions have opposite staining properties with mithramycin and quinacrine. Mithramycin labels the nucleolus organizer regions very brightly in the karyotypes of fishes, amphibians, reptiles and birds, but not of mammals. The lack of mithramycin fluorescence at the nucleolus organizer regions of mammals is attributed to the relatively low level of redundancy of the GC-rich ribosomal DNA in their genomes. Studies on the various meiotic stages of the cold-blooded vertebrates show that the mithramycin labeling of the nucleolus organizers is independent of their state of activity. This can be confirmed by mithramycin fluorescence at the nucleoli of actinomycintreated cells.Dedicated to the memory of Professor Dr. Hans Bauer     

Compositional properties of nuclear genes from cold-blooded vertebrates

Summary We have investigated the compositional properties of coding sequences from cold-blooded vertebrates and we have compared them with those from warm-blooded vertebrates. Moreover, we have studied the compositional correlations of coding sequences with the genomes in which they are contained, as well as the compositional correlations among the codon positions of the genes analyzed.The distribution of GC levels of the third codon positions of genes from cold-blooded vertebrates are distinctly different from those of warm-blooded vertebrates in that they do not reach the high values attained by the latter. Moreover, coding sequences from cold-blooded vertebrates are either equal, or, in most cases, lower in GC (not only in third, but also in first and second codon positions) than homologous coding sequences from warm-blooded vertebrates; higher values are exceptional. These results at the gene level are in agreement with the compositional differences between cold-blooded and warm-blooded vertebrates previously found at the whole genome (DNA) level (Bernardi and Bernardi 1990a,b).Two linear correlations were found: one between the GC levels of coding sequences (or of their third codon positions) and the GC levels of the genomes of cold-blooded vertebrates containing them; and another between the GC levels of third and first+ second codon positions of genes from cold-blooded vertebrates. The first correlation applies to the genomes (or genome compartments) of all vertebrates and the second to the genes of all living organisms. These correlations are tantamount to a genomic code.     

The possible functional role of neuronal gangliosides in temperature adaptation of vertebrates

Comparative studies on brain gangliosides of more than 60 vertebrate species show correlations between concentration and the level of evolutionary organization: poikilothermic lower vertebrates (fish, amphibs, reptiles) contain about 110 to 700 μg ganglioside bound NeuAc/g. fresh wt., homeothermic birds and mammals, on the other side, 500 to 1000 μg. The composition of brain gangliosides in poikilotherms is much more complex and variable (more multisialogangliosides) as compared with homeotherms (domination of less polar fractions). There are distinct correlations between brain ganglioside composition and state of thermal adaptation: Fishes being adapted to habitates with extreme temperatures (antarctic icefish — tropic fish) are characterized by quite opposite ganglioside patterns (domination of high versus less polar fractions). During seasonal acclimatization and experimental acclimation of fish to cold or during hibernation and early postnatal development of mammals poly-sialylations of brain gangliosides occur. With regard to this the individual brain structures react differently.

The results are taken for evidence that variations in the composion of synaptic membrane-bound gangliosides may induce long-term alterations in viscosity and permeability of the neuronal membrane by which the neuronal transmission might be kept on a constant level during the process of temperature adaptation.     

Hormone Specificity, Androgen Metabolism, and Social Behavior

SYNOPSIS. The ability of different sex hormones to activatesocial signals can provide important clues to the biochemicalmechanisms underlying these signals. A pattern of hormone specificityin which testosterone (T) and estradiol (E), but not dihydrotestosterone(DHT), are effective suggests that conversion (aromatization)of T to E in the brain may be involved or required; a patternin which T and DHT, but not E, are effective suggests that conversionof T to DHT may be involved. The hormone specificity of socialsignals in diverse species of vertebrates is reviewed. Aromatizationseems to be of widespread behavioral significance in mammalsandbirds. A role for conversion of T to DHT is suggested forsome signals. Aromatization of T mayalso be important for theactivation of adult female behavior in mammals and lizards,and for the early organization of behavior in mammals and birds.Patterns of hormone specificity differ both across species fora given social signal, and within a given species when differentsignals are compared. An attempt is made to integrate thesefindings by relating patterns of hormone specificity to hormonelevels, steroid receptor and enzyme concentrations and distributions,signal function and dimorphism, and phylogenetic status.     

A comparative study of soluble calcium-dependent proteolytic activity in brain

Recent studies have shown that soluble calcium activated proteases (calpains) in brain degrade proteins associated with the cytoskeleton and vary markedly in activity across regions and as a function of development. It was suggested that the observed differences in calpain activity reflect differences in the turnover rate of structural elements. The present study extends this analysis by measuring the properties and activity of calpain in representatives of the five classes of vertebrates with particular emphasis on the mammals. No evidence for proteolysis was found in soluble fractions of fish brains at neutral pH in the presence or absence of added calcium. A substantial calcium-independent proteolytic activity was found in amphibian brains—the effects of a variety of protease inhibitors indicated that it is also a neurtral thiol (cysteine) protease. Reptilian brains exhibited both calcium-independent and calcium-dependent proteolytic activity. Virtually all proteolytic activity in birds (5 species) and mammals (9 species) measured at neutral pH was calcium-dependent. The endogenous substrates for the calcium activated proteases were very similar in several species of birds and mammals as were the effects of a variety of protease inhibitors. However, the activity of the enzyme, expressed per mg of soluble protein, was highly and negatively correlated with brain size in the mammals. The allometric expression for this relationship was similar to that found for the density of neurons in cerebral cortex as a function of absolute brain size. These results indicate that soluble proteolytic enzymes in brain are differentially expressed among classes of vertebrates and suggest that the turnover of cytoskeletal elements in birds and mammals differs in important ways from that found in fish and amphibians. The results obtained for mammals raise the possibility of a relationship between brain size and the rate at which structural elements are broken down and replaced in this vertebrate class.     

RATES OF EVOLUTIONARY CHANGE IN CHROMOSOME NUMBERS IN SNAILS AND VERTEBRATES

Mollusks and most non-mammalian vertebrates have been characterized as evolving an order of magnitude more slowly in morphology and karyotype compared with most groups of placental mammals. New calculations of the previously used measures of chromosomal rates of evolution for different groups of gastropods, using a larger and taxonomically broader sample, indicate that these rates had been previously underestimated, although they are still lower than those of the most rapidly evolving placental groups. When genera of approximately the same geological age are compared, little difference (less than an order of magnitude) in fossil-based measures of average rate of karyotypic evolution are found among placental mammals, frogs, lizards, and snails. Variation in rates within major groups obtained from the limited available data does not allow clear generalizations on among-group differences in chromosomal rates of evolution.     

Rhodopsin Forms Nanodomains in Rod Outer Segment Disc Membranes of the Cold-Blooded Xenopus laevis

Rhodopsin forms nanoscale domains (i.e., nanodomains) in rod outer segment disc membranes from mammalian species. It is unclear whether rhodopsin arranges in a similar manner in amphibian species, which are often used as a model system to investigate the function of rhodopsin and the structure of photoreceptor cells. Moreover, since samples are routinely prepared at low temperatures, it is unclear whether lipid phase separation effects in the membrane promote the observed nanodomain organization of rhodopsin from mammalian species. Rod outer segment disc membranes prepared from the cold-blooded frog Xenopus laevis were investigated by atomic force microscopy to visualize the organization of rhodopsin in the absence of lipid phase separation effects. Atomic force microscopy revealed that rhodopsin nanodomains form similarly as that observed previously in mammalian membranes. Formation of nanodomains in ROS disc membranes is independent of lipid phase separation and conserved among vertebrates.     

Receptor Autoradiography as a Tool for the Study of the Phylogeny of the Basal Ganglia

Abstract

Recent studies on the neurotransmitter organization of the basal ganglia and forebrain in lower vertebrates suggest that, in contrast to the old concepts of the phylogeny of the brain, there are many similarities between the chemical organization of the brain throughout evolution. By examining neurotransmitter receptors using in vitro autoradiography we have attempted to further our understanding of the evolution of the brain. Receptors enriched in different parts of the basal ganglia in mammals appear to be also enriched in the homologous areas in lower vertebrates. Thus, for example, dopamine and muscarinic receptors, but not serotonin-1A, are enriched in the paleostriatum augmentatum while GABA/benzo-diazepine receptors are enriched in the paleostriatum primitivum corresponding with their localization to the caudate-putamen and globus pallidus respectively. Our results support the concept of a more conservative evolution of the vertebrate brain and demonstrate the usefulness of receptor autoradiography in the understanding of brain evolution.     

FATTY ACIDS AND LONG CHAIN BASES OF VERTEBRATE BRAIN GANGLIOSIDES

Abstract— Fatty acid and long-chain base composition of gangliosides from brains of animals belonging to various vertebrate classes (fishes, amphibia, reptiles, birds and mammals) was studied by gas-liquid chromatography. Stearic acid was found to be the main fatty acid everywhere. Brain gangliosides of cold-blooded animals contain lesser amounts of stearic and higher amounts of palmitic and monoenoic acids as compared to those of mammals. Long-chain bases were separated as trimethylsilyl derivatives. Large amounts (23-48 per cent) of long chain bases with 20 carbon atoms were found in brain gangliosides of mammals while in those of cold-blooded animals they constitute 3-12 per cent of the total. The comparison of the composition of gangliosides with that of cerebrosides and sulphatides indicates, that the fatty acid and long chain base composition of gangliosides from mammalian brain differs from that of other glycosphingolipids, whereas in brains of cold-blooded animals they are much more similar.     

Directional fixation of mutations in vertebrate evolution

Summary We have made pairwise comparisons between the coding sequences of 21 genes from coldblooded vertebrates and 41 homologous sequences from warm-blooded vertebrates. In the case of 12 genes, GC levels were higher, especially in third codon positions, in warm-blooded vertebrates compared to cold-blooded vertebrates. Six genes showed no remarkable difference in GC level and three showed a lower level. In the first case, higher GC levels appear to be due to a directional fixation of mutations, presumably under the influence of body temperature (see Bernardi and Bernardi 1986b). These GC-richer genes of warm-blooded vertebrates were located, in all cases studied, in isochores higher in GC than those comprising the homologous genes of cold-blooded vertebrates. In the third case, increases appear to be due to a limited formation of GC-rich isochores which took place in some cold-blooded vertebrates after the divergence of warm-blooded vertebrates. The directional changes in the GC content of coding sequences and the evolutionary conservation of both increased and unchanged GC levels are in keeping with the existence of compositional constraints on the genome.     

Choline Acetyltransferase Activities in Single Motor Neurons from Vertebrate Spinal Cords

Single cell bodies of spinal motor neurons were isolated from freeze-dried sections of fresh spinal cords from six species of vertebrates. Single human neurons were also isolated from the spinal cords of three autopsy cases without neurological diseases. Choline acetyltransferase activity of these single neurons was determined by measuring acetyl-CoA formation from CoASH and acetylcholine by use of the enzymatic amplification reactions, CoA and NADP cyclings. The enzyme activity was unevenly distributed in the cytosol of spinal motor neurons of all species, but not measurable in rabbit dorsal root ganglion cells. The specific activity on a dry weight basis varied widely among the individual neurons from the species studied. The average activity was highest with rat neurons and lowest with yellowtail neurons. The neurons from cold-blooded animals (bullfrog and yellowtail) had about one-tenth the activity compared with the warm-blooded animals (cat, rabbit, rat, and hen). Human neurons, obtained under different morbid and post-mortem conditions with three autopsy cases, had very low activities corresponding to those of cold-blooded animals. Since the choline acetyltransferase activity lost from mouse brain after 11 h at 38 degrees C was 50%, the activity in human neurons was believed to actually be low in vivo.     

A comparative analysis of allozyme variability in vertebrate animals]

Comparative analysis of levels of the allozymic variation in the vertebrates is conducted using evaluation of a) within population heterozygosity of ferment coding homologous loci, b) average (per each species) allele frequencies of homologous loci, and c) overall sample of the loci being analyzed. It is established that amphibians and reptiles are characterized by the highest, birds and mammals--by the lowest, and fishes--by the middle level of genetic diversity. The diversity of genetic systems, if the constant heterozygosity of duplicated loci is taken into consideration, decreases from fishes to mammals and from cold-blooded to warm-blooded vertebrates. This tendency could be considered as an extrapolation of the "progressive specialization" rule on molecular level. Three basic factors determining certain level of genetic diversity of a species are acknowledged position in the phylogenetic system, population structure, and level of introgressive hybridization. From methodological viewpoint, evaluation of the genetic diversity by homologous loci seems to be most valid in comparative studies.     

Central oxytocin receptors mediate mating-induced partner preferences and enhance correlated activation across forebrain nuclei in male prairie voles

Oxytocin (OT) is a deeply conserved nonapeptide that acts both peripherally and centrally to modulate reproductive physiology and sociosexual behavior across divergent taxa, including humans. In vertebrates, the distribution of the oxytocin receptor (OTR) in the brain is variable within and across species, and OTR signaling is critical for a variety of species-typical social and reproductive behaviors, including affiliative and pair bonding behaviors in multiple socially monogamous lineages of fishes, birds, and mammals. Early work in prairie voles suggested that the endogenous OT system modulates mating-induced partner preference formation in females but not males; however, there is significant evidence that central OTRs may modulate pair bonding behavior in both sexes. In addition, it remains unclear how transient windows of central OTR signaling during sociosexual interaction modulate neural activity to produce enduring shifts in sociobehavioral phenotypes, including the formation of selective social bonds. Here we re-examine the role of the central OT system in partner preference formation in male prairie voles using a selective OTR antagonist delivered intracranially. We then use the same antagonist to examine how central OTRs modulate behavior and immediate early gene (Fos) expression, a metric of neuronal activation, in males during brief sociosexual interaction with a female. Our results suggest that, as in females, OTR signaling is critical for partner preference formation in males and enhances correlated activation across sensory and reward processing brain areas during sociosexual interaction. These results are consistent with the hypothesis that central OTR signaling facilitates social bond formation by coordinating activity across a pair bonding neural network.