Molecular evolution of mammalian ribonucleases 1

There have been many studies on the chemistry of mammalian pancreatic ribonucleases (ribonucleases 1), but the functional biology of this family of homologous proteins is still largely unknown. Many studies have been performed on the molecular evolution and properties of this enzyme from species belonging to a large number of mammalian taxa, including paralogous gene products resulting from recent gene duplications. Novel ribonuclease 1 sequences were determined for three rodent species (gundi, brush-tailed porcupine, and squirrel), rabbit, a fruit bat, elephant, and aardvark, and the new sequences were used for deriving most parsimonious networks of ribonucleases from different mammalian orders, including earlier determined nucleotide sequences and also a larger set of protein sequences. Weak support for interordinal relationships were obtained, except for an Afrotheria clade containing elephant and aardvark. Results of current analyses and also those obtained 20 years ago on amino acid sequences confirm conclusions derived recently from larger data sets of other molecules. Several examples of recent gene duplications in ribonucleases 1 are discussed, with respect to illustrate the concepts of orthology and paralogy. Previously evidence was presented for extensive parallelism between sequence regions with attached carbohydrate (about one quarter of the molecule) of unrelated species with cecal digestion (pig and guinea pig). These features are also present in the sequences of elephant and fruit bat, species with cecal digestion, but with a very low ribonuclease content in their pancreas.     

Revisiting the action of bovine ribonuclease A and pancreatic-type ribonucleases on double-stranded RNA

Single-strand-preferring ribonucleases of the pancreatic type, structurally and/or catalytically similar to bovine RNase A but endowed with a higher protein basicity, are able to degrade double-stranded RNA (dsRNA) or DNA: RNA hybrids under standard assay conditions (0.15 M NaCl, 0.015 M sodium citrate, pH 7), where RNase A is inactive. This enzyme too, however, becomes quite active if assay conditions are slightly modified or its basicity is increased (polyspermine-RNase). In the attempt to review these facts, we have analyzed and discussed the role that in the process have the secondary structure of dsRNA as well as other variables whose influence has come to light in addition to that of the basicity of the enzyme protein, i.e., the ionic strength, the presence of carbohydrates on the RNase molecule, and the structure (monomeric or dimeric) of the enzyme. A possible mechanism by which dsRNAs are attacked by pancreatic-type RNases has been proposed.Abbreviations RNase Ribonuclease - dsRNA Double-stranded RNA - ssRNA Single-stranded RNA - poly(A) poly(U), poly(I) : poly(C) Double-stranded Homopolymers formed between Polyadenylate and Polyurydilate, and Polyinosinate and Polycytidylate, respectively - poly(dA): poly (rU) Double-stranded complex formed between Polydeoxyriboadenylate and Polyribouridylate - poly(A), poly(C) Polyadenylate and Polycytidylate, respectively - poly[d(A-T)] Double-stranded Homopolymers formed between Polydeoxyriboadenilate and Polydeoxyribothymidylate - poly(dA-dT) : poly (dA-dT) Double-stranded alternating copolymers - SSC 0.15 M Sodium Chloride, 0.015 M Sodium Citrate pH 7     

Ruminant brain ribonucleases: expression and evolution

Molecular evolutionary analyses of mammalian ribonucleases have shown that gene duplication events giving rise to three paralogous genes occurred in ruminant ancestors. One of these genes encodes a ribonuclease identified in bovine brain. A peculiar feature of this enzyme and orthologous sequences in other ruminants are C-terminal extensions consisting of 17-27 amino acid residues. Evidence was obtained by Western blot analysis for the presence of brain-type ribonucleases in brain tissue not only of ox, but also of sheep, roe deer and chevrotain (Tragulus javanicus), a member of the earliest diverged taxon of the ruminants. The C-terminal extension of brain-type ribonuclease from giraffe deviates much in sequence from orthologues in other ruminants, due to a change of reading frame. However, the gene encodes a functional enzyme, which could be expressed in heterologous systems. The messenger RNA of bovine brain ribonuclease is not only expressed at a high level in brain tissue but also in lactating mammary gland. The enzyme was isolated and identified from this latter tissue, but was not present in bovine milk, although pancreatic ribonucleases A and B could be isolated from both sources. This suggests different ways of secretion of the two enzyme types, possibly related to structural differences. The sequence of the brain-type RNase from chevrotain suggests that the C-terminal extensions of ruminant brain-type ribonucleases originate from deletions in the ancestral DNA (including a region with stop codons), followed by insertion of a 5-8-fold repeated hexanucleotide sequence, coding for a proline-rich polypeptide.     

Molecular design of artificial ribonucleases using electrostatic interaction

A number of small organic ribonucleases have been synthesized with rigid polycationic structures containing an aromatic framework with two residues of bis-quaternary salts of 1,4-diazabicyclo[2.2.2]octane (DABCO) bearing various substituents. The compounds carrying positively charged groups connected via rigid linker are expected to bend the sugar-phosphate backbone and can stimulate the intramolecular phosphoester transfer reaction.     

Zebrafish RNase T2 genes and the evolution of secretory ribonucleases in animals

Background  

Members of the Ribonuclease (RNase) T2 family are common models for enzymological studies, and their evolution has been well characterized in plants. This family of acidic RNases is widespread, with members in almost all organisms including plants, animals, fungi, bacteria and even some viruses. While several biological functions have been proposed for these enzymes in plants, their role in animals is unknown. Interestingly, in vertebrates most of the biological roles of plant RNase T2 proteins are carried out by members of a different family, RNase A. Still, RNase T2 proteins are conserved in these animals     

Molecular evolution of poxviruses

Previous restriction fragment length polymorphism analysis divided variola virus (VARV) strains into two subtypes, one of which included West African and South American isolates. This allowed a dating to be introduced for the first time in estimation of the VARV evolution rate. The results were used to analyze the molecular evolution of the total family Poxviridae. Comparisons of the known nucleotide sequences were performed for the extended conserved central genome region in 42 orthopoxvirus strains and for the eight genes of multisubunit RNA polymerase in 65 viruses belonging to various genera of the family Poxviridae. Using the Bayesian dating method, the mutation accumulation rate of poxviruses was estimated at (1.7-8.8) x 10(-6) nucleotide substitutions per site per year. Computations showed that the modem poxvirus genera started diverging from an ancestral virus more than 200 thousand years ago and that an ancestor of the genus Orthopoxvirus emerged 131 +/- 45 thousand years ago. The other genera of mammalian poxviruses with a low GC content diverged approximately 110-90 thousand years ago. The independent evolution of VARV started 3.4 +/- 0.8 thousand years ago. It was shown with the example of VARV and the monkeypox virus (MPXV) that divergent evolution of these orthopoxviruses started and the West African subtypes of VARV and MPXV were formed as geographical conditions changed to allow isolation of West African animals from other African regions.     

Molecular evolution of proglucagon

The vertebrate proglucagon gene encodes glucagon, and the two glucagon-like peptides GLP-1 and GLP-2. To better understand the origin and diversification of the distinct hormonal roles of the three glucagon-like sequences encoded by the proglucagon gene, we have examined the evolution of this gene. The structure of proglucagon has been largely maintained within vertebrates. Duplication of the proglucagon gene or duplications of sequences within the proglucagon gene are rare. All proglucagon gene duplications are likely to be the result of genome duplication events. Examination of the rates of amino acid sequence evolution of each hormone reveals that they have not evolved in a uniform manner. Each hormone has evolved in an episodic fashion, suggesting that the selective constraints acting upon the sequence vary between, and within, vertebrate classes. Changes in selection on a sequence often reflect changes in the function of the sequence, such as the change in function of GLP-1 from a glucagon-like hormone in fish to an incretin in mammals. We found that the GLP-2 sequence underwent rapid sequence evolution in the early mammal lineage, therefore we have concluded that mammalian GLP-2 has acquired a new biological function that is not found in other vertebrates. Comparisons of the hormone sequences show that many amino acid residues that are functionally important in mammalian hormones are not conserved through vertebrate evolution. This observation suggests that the sequences involved in hormone action change through evolution.     

Molecular evolution of enolase

Enolase (EC 4.2.1.11) is an enzyme of the glycolytic pathway catalyzing the dehydratation reaction of 2-phosphoglycerate. In vertebrates the enzyme exists in three isoforms: alpha, beta and gamma. The amino-acid and nucleotide sequences deposited in the GenBank and SwissProt databases were subjected to analysis using the following bioinformatic programs: ClustalX, GeneDoc, MEGA2 and S.I.F.T. (sort intolerant from tolerant). Phylogenetic trees of enolases created with the use of the MEGA2 program show evolutionary relationships and functional diversity of the three isoforms of enolase in vertebrates. On the basis of calculations and the phylogenetic trees it can be concluded that vertebrate enolase has evolved according to the "birth and death" model of evolution. An analysis of amino acid sequences of enolases: non-neuronal (NNE), neuron specific (NSE) and muscle specific (MSE) using the S.I.F.T. program indicated non-uniform number of possible substitutions. Tolerated substitutions occur most frequently in alpha-enolase, while the lowest number of substitutions has accumulated in gamma-enolase, which may suggest that it is the most recently evolved isoenzyme of enolase in vertebrates.     

Inhibitors of ribonucleases

RNases are the most important enzymes of cellular metabolism. They influence gene expression, cell growth and differentiation, participate in cell protection against pathogens and induction of apoptosis. Since intracellular RNases exist mainly in complexes with their inhibitors, the latter are also involved in all above-mentioned processes. The review describes natural protein inhibitors of animal, plant, and bacterial RNases along with synthetic low molecular-weight inhibitors. Special attention is paid to the perspectives of application of RNase inhibitors to therapy of oncological and allergic diseases. Despite wide distribution of RNases and their numerous studies, the number of available natural and synthetic inhibitors of these enzymes remains limited. Creation of highly efficient low-molecular inhibitors of RNase activity of angiogenin and eosinophil-associated RNases, aimed at the therapy of oncological and allergic diseases, still remains quite actual.     

RNase T2 genes from rice and the evolution of secretory ribonucleases in plants

The plant RNase T2 family is divided into two different subfamilies. S-RNases are involved in rejection of self-pollen during the establishment of self-incompatibility in three plant families. S-like RNases, on the other hand, are not involved in self-incompatibility, and although gene expression studies point to a role in plant defense and phosphate recycling, their biological roles are less well understood. Although S-RNases have been subjects of many phylogenetic studies, few have included an extensive analysis of S-like RNases, and genome-wide analyses to determine the number of S-like RNases in fully sequenced plant genomes are missing. We characterized the eight RNase T2 genes present in the Oryza sativa genome; and we also identified the full complement of RNase T2 genes present in other fully sequenced plant genomes. Phylogenetics and gene expression analyses identified two classes among the S-like RNase subfamily. Class I genes show tissue specificity and stress regulation. Inactivation of RNase activity has occurred repeatedly throughout evolution. On the other hand, Class II seems to have conserved more ancestral characteristics; and, unlike other S-like RNases, genes in this class are conserved in all plant species analyzed and most are constitutively expressed. Our results suggest that gene duplication resulted in high diversification of Class I genes. Many of these genes are differentially expressed in response to stress, and we propose that protein characteristics, such as the increase in basic residues can have a defense role independent of RNase activity. On the other hand, constitutive expression and phylogenetic conservation suggest that Class II S-like RNases may have a housekeeping role.     

Molecular bases of evolution

The general notions of the theory of evolution are listed. The unity of the "engineering principles" of the living nature is emphasized. The generalists and specialists species are discussed. The estimation of their evolution rates must be different if it is expressed by the number of species or by the morphological changes. The principles of "protein engineering" of the organisms and the role of metals in protein evolution are discussed. It is suggested that in the presence of ions of transition metals and zinc the Fox's proteinoids can possess more specific forms of enzymatic activity. In the evolution of language the horizontal transfer plays a much more important role than in the biological evolution. However in this case also the initial basis of the language remains. The random drift is considered and it is shown that in concordance with the neutralist theory there are no grounds to replace the calculation of the rates of mutational changes per time unity by the calculation per generation. The molecular drive is the main source of the evolutionary novelties. The drive is connected with drift. The synonymic mutations and the mutations in non-functional DNA are evolutionary important. The future mathematical theory of evolution must be based on the theory of Markov's chains with the stochastic matrix changing along the chain and containing the set of the non-diagonal members equal to zero. The results obtained in the theory of ontogeny are presented. The evolution of species is the evolution of ontogenies, the formation of the molecular theory of evolution can be possible only on the basis of the molecular theory of ontogeny. The internal causes of extinction of species reduce the accumulation of neutral and pseudo-neutral mutations.     

Molecular evolution of poxviruses

Previous restriction fragment length polymorphism analysis divided variola virus (VARV) strains into two subtypes, one of which included West African and South American isolates. This allowed a dating to be introduced for the first time in estimation of the VARV evolution rate. The results were used to analyze the molecular evolution of the total family Poxviridae. Comparisons of the known nucleotide sequences were performed for the extended conserved central genome region in 42 orthopoxvirus strains and for the eight genes of multisubunit RNA polymerase in 65 viruses belonging to various genera of the family Poxviridae. Using the Bayesian dating method, the mutation accumulation rate of poxviruses was estimated at (1.7–8.8) × 10^?6 nucleotide substitutions per site per year. Computations showed that the modern poxvirus genera started diverging from an ancestral virus more than 200 thousand years ago and that an ancestor of the genus Orthopoxvirus emerged 131 ± 45 thousand years ago. The other genera of mammalian poxviruses with a low GC content diverged approximately 110–90 thousand years ago. The independent evolution of VARV started 3.4 ± 0.8 thousand years ago. It was shown with the example of VARV and the monkeypox virus (MPXV) that divergent evolution of these orthopoxviruses started and the West African subtypes of VARV and MPXV were formed as geographical conditions changed to allow isolation of West African animals from other African regions.