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 isochore patterns of mammalian genomes and their phylogenetic implications

The compositional distributions of high molecular weight DNA fragments from 20 species belonging to 9 out of the 17 eutherian orders were investigated by analytical CsCl density gradient centrifugation and by preparative fractionation in Cs₂SO₄/BAMD density gradients followed by analysis of the fractions in CsCl. These compositional distributions reflect those of the isochores making up the corresponding genomes. A “general distribution” was found in species belonging to eight mammalian orders. A “myomorph distribution” was found in Myomorpha, but not in the other rodent infraorders Sciuromorpha and Histricomorpha, which share the general distribution. Two other distributions were found in a megachiropteran (but not in microchiropteran, which, again, shares the general distribution) and in pangolin (a species from the only genus of the order Pholidota), respectively. The main difference between the general distribution and all other distributions is that the former contains sizable amounts (6–10%) of GC-rich isochores (detected as DNA fragments equal to, or higher than, 1.710 g/cm³ in modal buoyant density), which are scarce, or absent, in the other distributions. This difference is remarkable because gene concentrations in mammalian genomes are paralleled by GC levels, the highest gene concentrations being present in the GC-richest isochores. The compositional distributions of mammalian genomes reported here shed light on mammalian phylogeny. Indeed, all orders investigated, with the exception of Pholidota, seem to share a common ancestor. The compositional patterns of the megachiropteran and of Myomorpha may be derived from the general pattern or have independent origins.     

Compositional patterns in reptilian genomes

Sauropsids form a complex group of vertebrates including squamates (lizards and snakes), turtles, crocodiles, sphenodon and birds (which are often considered as a separate class). Although avian genomes have been relatively well studied, the genomes of the other groups have remained only sparsely characterized. Moreover, the nuclear sequences available in databanks are still very limited. In the present study, we have analysed the compositional patterns, i.e. the GC (molar fraction of guanine and cytosine in DNA) distributions, of 31 reptilian (particularly snake) genomes by analytical ultracentrifugation of DNAs in CsCl gradients. The profiles were characterized by their modal buoyant density rho(o), mean buoyant density < rho>, asymmetry < rho>- rho(o), and heterogeneity H. The modal buoyant density distribution of reptilian DNAs clearly distinguishes two groups. The snakes fall in the same range of modal densities as most mammals, whereas crocodiles, turtles and lizards show higher values (>1.700 g/cm(3)). As far as the more important compositional properties of asymmetry and heterogeneity are concerned, previous studies showed that amphibians and fishes share relatively low values, whereas birds and mammals are characterized by highly heterogeneous and asymmetric patterns (with the exception of Muridae, which have a lower heterogeneity). The present results show that the snake genomes cover a broad range of asymmetry and heterogeneity values, whereas the genomes of crocodiles and turtles cover a narrow range that is intermediate between those of fishes/amphibians and those of mammals/birds.     

Compositional patterns in the nuclear genome of cold-blooded vertebrates

Summary DNA preparations obtained from 122 species of fishes, 5 species of amphibians, and 13 species of reptiles were investigated in their compositional properties by analytical equilibrium centrifugation in CsCl density gradients. These species represented 21 orders of Osteichthyes, 3 orders of Chondrichthyes, 2 orders of amphibians, and 3 orders of reptiles. Modal buoyant densities of fish DNAs ranged from 1.696 to 1.707 g/cm³, the vast majority of values falling, however, between 1.699 and 1.704 g/cm³, which is the range covered by the DNAs of amphibians and reptiles. In all cases, DNA bands in CsCl were only weakly asymmetrical and only very rarely were accompanied by separate satellite bands (mostly on the GC-rich side). Intermolecular compositional heterogeneities were low in the vast majority of cases, and, like CsCl band asymmetries, at least partially due to cryptic or poorly resolved satellites. The present findings indicate, therefore, that DNAs from cold-blooded vertebrates are characterized by a number of common properties, namely a very wide spectrum of modal buoyant densities, low intermolecular compositional heterogeneities, low CsCl band asymmetries, and, in most cases, small amounts of satellite DNAs. In the case of fish DNAs a negative correlation was found between the GC level and the haploid size (c value) of the genome. If polyploidization is neglected, this phenomenon appears to be mainly due to the fact that increases and decreases in GC are associated with contraction and expansion phenomena, respectively, of intergenic noncoding sequences, which are GC poor relative to coding sequences.     

The compositional distribution of coding sequences and DNA molecules in humans and murids

Summary The compositional distributions of coding sequences and DNA molecules (in the 50-100-kb range) are remarkably narrower in murids (rat and mouse) compared to humans (as well as to all other mammals explored so far). In murids, both distributions begin at higher and end at lower GC values. A comparison of homologous coding sequences from murids and humans revealed that their different compositional distributions are due to differences in GC levels in all three codon positions, particularly of genes located at both ends of the distribution. In turn, these differences are responsible for differences in both codon usage and amino acids. When GC levels at first+second codon positions and third codon positions, respectively, of murid genes are plotted against corresponding GC levels of homologous human genes, linear relationships (with very high correlation coefficients and slopes of about 0.78 and 0.60, respectively) are found. This indicates a conservation of the order of GC levels in homologous genes from humans and murids. (The same comparison for mouse and rat genes indicates a conservation of GC levels of homologous genes.) A similar linear relationship was observed when plotting GC levels of corresponding DNA fractions (as obtained by density gradient centrifugation in the presence of a sequence-specific ligand) from mouse and human. These findings indicate that orderly compositional changes affecting not only coding sequences but also noncoding sequences took place since the divergence of murids. Such directional fixations of mutations point to the existence of selective pressures affecting the genome as a whole.     

Density gradient analysis of newly replicated DNA from synchronized mouse lymphoma cells

The replication of DNA in synchronous cultures of mouse lymphoma cells was investigated by use of CsCl density gradient centrifugation. We found that the buoyant density of newly replicated DNA depended upon the particular stage of S phase in which synthesis occurred. In early S phase, newly replicated DNA exhibited buoyant densities which were slightly higher, on the average, than that of pre-existing DNA. As S phase progressed, newly replicated DNA shifted to lower buoyant densities, until, near the end of S phase, densities less than pre-existing DNA were observed. These observations are discussed in terms of their possible relevance to base compositional differences between nucleotide sequences made in early as opposed to middle or late S phase.     

An ultracentrifugation analysis of two hundred fish genomes

The goal of this study was to provide a comprehensive view of the compositional characteristics of fish genomes. We therefore expanded the number of fish species that we had explored so far in their DNAs by analytical ultracentrifugation in CsCl density gradient from 122 to 201. This study included representatives from three out of nine orders of Elasmobranchs (sharks and rays), both orders of dipnoan lungfishes, and both orders of chondrosteans (sturgeons and bichirs). We also studied 19 out of 38 teleostean orders, which represent all but four (minor) superorders of the subdivision Teleostei, a group comprising about 23,600 species (96% of all extant fishes). This leaves for further studies two subclasses, Holocephali (chimaeras), and Coelacanthimorpha (gombessas). In spite of this substantial increase in the number of species and orders analysed, all average properties (the modal buoyant density, rho(0), the average buoyant density, , the CsCl profile asymmetry, A, and the compositional heterogeneity, H), and all their ranges were unchanged compared to a previous study [J. Mol. Evol. 31 (1990) 265]. This suggests that, in all likelihood, the properties reported in the present paper can be considered as generally valid for all fish genomes.     

Long-branch attraction phenomenon and the impact of among-site rate variation on rodent phylogeny

The phylogenetic relationships among major lineages of rodents is one of the issues most debated by both paleontologists and molecular biologists. In the present study, we have analyzed all complete mammalian mitochondrial genomes available in the databases, including five rodent species (rat, mouse, dormouse, squirrel and guinea-pig). Phylogenetic analyses were performed on H-strand amino acid sequences by means of maximum-likelihood and on H-strand protein-coding and ribosomal genes by means of distance methods. Also, log-likelihood ratio tests were applied to different tree topologies under the assumption of rodent monophyly, paraphyly or polyphyly. The analyses significantly rejected rodent monophyly and showed the existence of two differentiated clades, one containing non-murids (dormouse, squirrel and guinea-pig) and the other containing murids (rat and mouse). Long-branch attraction between murids and the outgroups could not be responsible for the existence of two different rodent clades, as no significant differences in evolutionary rate have been observed, except in the case of the squirrel, which shows a lower rate. The impact of among-site rate variation models on the phylogeny of rodents has been evaluated using the gamma distribution model. Results have shown that relationships among rodents remained unchanged, and the general topology of the tree was not affected, even though some branches were not properly resolved, most likely due to a lack of fit between estimated and real rate heterogeneity parameters.     

Fractionation and characterization of satellite DNAs of the kangaroo rat (Dipodomys ordii)

Nuclear DNA from liver cells of the kangaroo rat species Dipodomysordii was fractionated and characterized with the aid of buoyant density gradients in neutral and alkaline CsCl and in Ag⁺-Cs₂SO₄. More than one-half of the DNA was present in three density satellites, a greater proportion than in any other species yet reported; the purified satellite DNAs were denser than principal DNA. All satellite fractions revealed sharp isopycnic bands and narrow denaturation profiles. Two had identical buoyant densities but differed substantially in T_m, base composition, and reassociation kinetics. In alkaline CsCl all three satellites, as well as a shoulder of intermediate repetitive DNA on the heavy side of the principal band, revealed unique strand densities. The most highly repetitive satellite was unusually rich in (G + C) and contained 6.7% of 5-methylcytosine. A survey of internal organs and spermatozoa of an adult male revealed no significant differences in distribution of the satellites among tissues.     

Enamel Microstructure of Rodent Molars, Classification, and Parallelisms, with a Note on the Systematic Affiliation of the Enigmatic Eocene Rodent Protoptychus

To investigate the diversity of the enamel structures in rodent molars, the schmelzmuster of more than 270 genera from the various fossil and extant groups was investigated. Only three basic types of schmelzmuster were recognized. The most prominent one, the C-type, is characterized by a basal ring of lamellar enamel (BRLE) surrounding the molars at the base of the crown. It occurs in most murids (cricetids) and other Myodonta. It is shared by the Dipodidea, Eomyidae, Geomyidae, and Gliridae. The C-type schmelzmuster was not found in any of the other rodents groups (Sciuromorpha, Anomaluromorpha, Sciuravida, Hystricognathi, Bathyergomorphi, and Caviida). Despite the rare occurrence of the P-type schmelzmuster with radial enamel only, most of these rodents have thick Hunter–Schreger bands (HSB) in their molars (S-type schmelzmuster). Although the C-type schmelzmuster is strictly limited to the Myomorpha (sensu McKenna and Bell), the fossil record shows that this structure does not form a synapomorphy but developed in parallel mostly from the P-type, but in Gliridae from the S-type schmelzmuster. On the basis of molar and incisor enamel the systematic position of Protoptychus can be evaluated.     

Population dynamics of a diverse rodent assemblage in mixed grass-shrub habitat, southeastern Colorado, 1995-2000

We followed seasonal and year-to-year population dynamics for a diverse rodent assemblage in a short-grass prairie ecosystem in southeastern Colorado (USA) for 6 yr. We captured 2,798 individual rodents (range, one to 812 individuals per species) belonging to 19 species. The two most common species, deer mice (Peromyscus maniculatus) and western harvest mice (Reithrodontomys megalotis), generally had population peaks in winter and nadirs in summer; several other murid species demonstrated autumn peaks and spring nadirs; heteromyids were infrequently captured in winter, and populations generally peaked in summer or autumn. Inter-annual trends indicated an interactive effect between temperature and precipitation. Conditions associated with low rodent populations or population declines were high precipitation during cold periods (autumn and winter) and low precipitation during warm periods (spring and summer). Severity of adverse effects varied by species. Heteromyids, for example, were apparently not negatively affected by the hot, dry spring and summer of 2000. Cross-correlations for the temporal series of relative population abundances between species pairs (which are affected by both seasonal and interannual population dynamics) revealed positive associations among most murids and among most heteromyids, but there were negative associations between murids and heteromyids. These results have important implications for those attempting to model population dynamics of rodent populations for purposes of predicting disease risk.     

A glimpse on the pattern of rodent diversication: a phylogenetic approach

ABSTRACT: BACKGROUND: Development of phylogenetic methods that do not rely on fossils for the study of evolutionary processes through time have revolutionized the eld of evolutionary biology and resulted in an unprecedented expansion of our knowledge about the tree of life. These methods have helped to shed light on the macroevolution of many taxonomic groups such as the placentals (Mammalia). However, despite the increase of studies addressing the diversication patterns of organisms, no synthesis has addressed the case of the most diversied mammalian clade: the Rodentia. RESULTS: Here we present a rodent maximum likelihood phylogeny inferred from a molecular supermatrix. It is based on 11 mitochondrial and nuclear genes that covers 1,265 species, i.e., respectively 56 % and 81 % of the known specic and generic rodent diversity. The inferred topology recovered all Rodentia clades proposed by recent molecular works. A relaxed molecular clock dating approach provided a time framework for speciation events. We found that the Myomorpha clade shows a greater degree of variation in diversication rates than Sciuroidea, Caviomorpha, Castorimorpha and Anomaluromorpha. We identied a number of shifts in diversication rates within the major clades: two in Castorimorpha, three in Ctenohystrica, 6 within the squirrel-related clade and 24 in the Myomorpha clade. The majority of these shifts occurred within the most recent familial rodent radiations: the Cricetidae and Muridae clades. Using the topological imbalances and the time line we discuss the potential role of different diversication factors that might have shaped the rodents radiation. CONCLUSIONS: The present glimpse on the diversication pattern of rodents can be used for further comparative meta-analyses. Muroid lineages have a greater degree of variation in their diversication rates than any other 1rodent group. Different topological signatures suggest distinct diversication processes among rodent lineages. In particular, Muroidea and Sciuroidea display widespread distribution and have undergone evolutionary and adaptive radiation on most of the continents. Our results show that rodents experienced shifts in diversication rate regularly through the Tertiary, but at different periods for each clade. A comparison between the rodent fossil record and our results suggest that extinction led to the loss of diversication signal for most of the Paleogene nodes.     

Using analytical ultracentrifugation to study compositional variation in vertebrate genomes

Although much attention has recently been directed to analytical ultracentrifugation (AUC), the revival of interest has hardly addressed the applications of this technology in genome analysis, and the extent to which AUC studies can quickly and effectively complement modern sequence-based analyses of genomes, e.g. by anticipating, extending or checking results that can be obtained by cloning and sequencing. In particular, AUC yields a quick overview of the base compositional structure of a species' genome even if no DNA sequences are available and the species is unlikely to be sequenced in the near future. The link between AUC and DNA sequences dates back to 1959, when a precise linear relation was discovered between the GC (guanine+cytosine) level of DNA fragments and their buoyant density in CsCl as measured at sedimentation equilibrium. A 24-hour AUC run of a high molecular weight sample of a species' total DNA already yields the GC distribution of its genome. AUC methods based on this principle remain sensitive tools in the age of genomics, and can now be fine-tuned by comparing CsCl absorbance profiles with the corresponding sequence histograms. The CsCl profiles of vertebrates allow insight into structural and functional properties that correlate with base composition, and their changes during vertebrate evolution can be monitored by comparing CsCl profiles of different taxa. Such comparisons also allow consistency checks of phylogenetic hypotheses at different taxonomic levels. We here discuss some of the information that can be deduced from CsCl profiles, with emphasis on mammalian DNAs.     

Evolutionary evidence for a regulator gene controlling the lactate dehydrogenase B gene in rodent erythrocytes

Erythrocyte and tissue lactate dehydrogenase (LDH) electrophoretic patterns of 26 rodent species from ten families were examined. The LDH B gene was observed to range in erythrocyte expression from species without detectable B subunits to those which predominantly expressed B subunits. However, the shift in erythrocyte B gene expression was not observed in the tissue LDH electrophoretic patterns between rodent species. Species which did not express erythrocyte B subunits, or only small quantities of B subunits, were restricted to the suborder Myomorpha. In erythrocytes of other rodent species, and most mammals, LDH B subunits are expressed equally or in excess of A subunits. The results suggest either structural differences in the LDH B gene between Myomorph and non-Myomorph rodents or a regulator gene which controls the expression of the B gene in Myomorph erythrocytes. Existing evidence favors the latter hypothesis.Supported by U.S. Public Health Service Grants 5F2 HD-35,531 (T.B.S.), GM-09966 (F.H.R.), G.R.S. 5 SO1 FR-05400-07, and NSF GB 5440X (E.J.M.).     

DNA from Maize with and without B Chromosomes: A Comparative Study

DNA preparations from 5B and 0B maize seedlings are indistinguishable in their buoyant density distribution in CsCl gradients. Their renaturation kinetics are identical at several stringency criteria. DNA competition studies fail to detect any component in 5B DNA redundant sequences which is lacking in 0B DNA. Homologous and heterologous duplexes formed between 5B and 0B DNA have virtually identical melting profiles. The DNA of B chromosomes is concluded to be very closely related to that of A chromosomes.     

Buoyant densities of DNA of mammals

One characteristic of DNA, CsCl buoyant density peak values, was determined for DNA samples isolated from 93 species belonging to 11 orders of mammals. The CsCl buoyant density values varied over a very narrow range, 1.696–1.701 g/cm³. Satellite DNAs were found in a number of species. The function and origin of these satellite DNAs are not known.This work was supported by grant DRG-269 from the Damon Runyon Memorial Fund for Cancer Research, Inc., and GB-6657 from the National Science Foundation.     

Monophyly or polyphyly of the order Rodentia: Possible conflict between morphological and molecular interpretations

Recent analyses of amino acid sequence data from selected proteins inCavia, Rattus, Homo, Bos, Sus, and a few additional rodents and other eutherians suggested that Rodentia is not a monophyletic taxon and thatCavia and other hystricognaths may have branched off earlier than the separation between Muroidea and Primates during mammalian evolution. Because this hypothesis of polyphyly is contrary to the otherwise unanimous recognition of rodent monophyly, we have reevaluated the morphological and developmental evidence from the cranium, dentition, postcranial skeleton, and fetal membranes for the taxa Hystricognathi, Muroidea, other Rodentia, Primates, Artiodactyla, and Lagomorpha, as well as for the eutherian morphotype. Our character analyses provide strong corroboration for the traditional hypothesis of rodent monophyly and lend additional support to the suggestion that Lagomorpha is the sister taxon of Rodentia. Our survey of published molecular data furnishes little or no support for the proposed hypothesis of rodent polyphyly. We conclude that this hypothesis is the result of poor sampling of sequence data from rodents and other eutherians, rather than any inherent difficulties in the use of molecular evidence for the assessment of mammalian evolution. The available molecular data suggest thatCavia differs considerably from other hystricognaths in many proteins, but the reasons for this remain to be investigated.     

Evolution of isochores in rodents

The most deviant isochore pattern within mammals was found in rat and mouse; most other mammals possess a different kind of isochore organization called the "general pattern." However, isochore patterns remain largely unknown in rodents other than mouse and rat. To investigate the taxonomic distribution of isochore patterns in rodents, we sequenced the nuclear gene LCAT (lecithin:cholesterol acyltransferase) from 17 rodents species (bringing the total of LCAT sequences in rodent to 19) and compared their GC contents at third codon positions and in introns. We also analyzed an extensive sequence database from rodents other than rat and mouse. All murid LCAT sequences are much poorer in GC than all nonrodent LCAT sequences, and the hamster sequence database shows exactly the same isochore pattern as rat and mouse. Thus, all murids share the same special isochore pattern--GC homogenization. LCAT sequences are GC-poor in hystricomorphs too, but the guinea pig sequence database indicates that large changes in GC content occur without an overall modification of the isochore pattern. This novel mode of isochore evolution is called GC reordering. LCAT sequences also show that the evolution of isochores in sciurids and glirids is nonconservative in comparison with that in nonrodents. Thus, at least two novel patterns of isochore evolution were found. No rodent investigated to date shared the general mammalian pattern.      

The properties of native and denatured DNA in buoyant rubidium trichloroacetate at neutral pH

Aqueous RbTCA is generally suitable as a buoyant solvent for both native and denatured DNA at neutral pH and room temperature. Native PM-2 DNA II, for example, is buoyant at 3.29 M salt, 25 degrees C; whereas the denatured strands band together at 4.52 M. Two properties of the solvent make this system uniquely useful for separations based upon the extent of secondary structure. First, the melting transition temperature for chemically unaltered DNA is depressed to room temperature or below. Second, the buoyant density increase accompanying denaturation is extraordinarily large, 174 mg/ml for PM-2 DNA II. This value is three times that found in aqueous NaI and ten times that for CsCl. The properties of the RbTCA buoyant solvent presented here include the compositional and buoyant density gradients and the buoyant density dependence upon base composition. The DNA remains chemically unaltered after exposure to RbTCA as shown by the absence of strand scissions for closed circular DNA and by the unimpaired biological activity in transformation assays. Intact virion DNA may be isolated by direct banding of whole virions in RbTCA gradients without prior phenol extraction. Strongly complexed or covalently bound proteins may be detected by their association with the buoyant polymer in the denaturing density gradient.     

Higher-level systematics of rodents and divergence time estimates based on two congruent nuclear genes

Phylogenetic analysis of over 4600 aligned nucleotide sequences from two nuclear genes, growth hormone receptor and BRCA1, provided congruent phylogenies depicting relationships among the major lineages of rodents. Separate and combined analyses resulted in five major conclusions: (1) strong support for a monophyletic Myodonta (containing the superfamilies Muroidea + Dipodoidea), with subfamily Gerbillinae being more closely related to Murinae than is Sigmodontinae; (2) a sister-group relationship between the family Castoridae and the superfamily Geomyoidea; (3) monophyly of Ctenohystrica (containing the suborders Sciuravida and Hystricognatha); (4) a near polytomy among Myodonta (suborder Myomorpha), Pedetes (family Pedetidae, suborder Anomaluromorpha), Castoridae (suborder Sciuromorpha) + Geomyoidea (suborder Myomorpha), and Ctenohystrica; and (5) basal position of a monophyletic group containing Graphiurus (family Gliridae, suborder Myomorpha) + two members of the Sciuromorpha (Sciuridae + Aplodontidae). Divergence dates among rodents and primates were also estimated using the combined data. Applying a global molecular clock and a primate calibration point, divergence dates among rodents exceeded fossil-based dates but were generally compatible with other molecule-based dates estimated under similar conditions. However, when a relaxed molecular clock was applied, estimated divergence dates were highly compatible with the fossil record.