Structural evolution and functional diversification analyses of argonaute protein

Argonaute (AGO) proteins are highly specialized small-RNA-binding modules and small RNAs are anchored to their specific binding pockets guiding AGO proteins to target mRNA molecules for silencing or destruction. The 135 full-length AGO protein sequences derived from 36 species covering prokaryote, archaea, and eukaryote are chosen for structural and functional analyses. The results show that bacteria and archaeal AGO proteins are clustered in the same clade and there exist multiple AGO proteins in most eukaryotic species, demonstrating that the increase of AGO gene copy number and horizontal gene transfer (HGT) have been the main evolutionary driving forces for adaptability and biodiversity. And the emergence of PAZ domain in AGO proteins is the unique evolutionary event. The analysis of middle domain (MID)-nucleotide contaction shows that either the position of sulfate I bond in Nc_QDE2 or the site of phosphate I bond in Hs_AGO2 represents the 5'-nucleotide binding site of miRNA. Also, H334, T335, and Y336 of Hs_AGO1 can form hydrogen bonds with 3'-overhanging ends of miRNAs and the same situation exists in Hs_AGO2, Hs_AGO3, Hs_AGO4, Dm_AGO1, and Ce_Alg1. Some PIWI domains containing conserved DDH motif have no slicer activity, and post-translational modifications may be associated with the endonucleolytic activities of AGOs. With the numbers of AGO genes increasing and fewer crystal structures available, the evolutionary and functional analyses of AGO proteins can help clarify the molecular mechanism of function diversification in response to environmental changes, and solve major issues including host defense mechanism against virus infection and molecular basis of disease.     

Constant relative rate of protein evolution and detection of functional diversification among bacterial, archaeal and eukaryotic proteins

Background  

Detection of changes in a protein's evolutionary rate may reveal cases of change in that protein's function. We developed and implemented a simple relative rates test in an attempt to assess the rate constancy of protein evolution and to detect cases of functional diversification between orthologous proteins. The test was performed on clusters of orthologous protein sequences from complete bacterial genomes (Chlamydia trachomatis, C. muridarum and Chlamydophila pneumoniae), complete archaeal genomes (Pyrococcus horikoshii, P. abyssi and P. furiosus) and partially sequenced mammalian genomes (human, mouse and rat).     

Globin gene family evolution and functional diversification in annelids

Globins are the most common type of oxygen-binding protein in annelids. In this paper, we show that circulating intracellular globin (Alvinella pompejana and Glycera dibranchiata), noncirculating intracellular globin (Arenicola marina myoglobin) and extracellular globin from various annelids share a similar gene structure, with two conserved introns at canonical positions B12.2 and G7.0. Despite sequence divergence between intracellular and extracellular globins, these data strongly suggest that these three globin types are derived from a common ancestral globin-like gene and evolved by duplication events leading to diversification of globin types and derived functions. A phylogenetic analysis shows a distinct evolutionary history of annelid extracellular hemoglobins with respect to intracellular annelid hemoglobins and mollusc and arthropod extracellular hemoglobins. In addition, dehaloperoxidase (DHP) from the annelid, Amphitrite ornata, surprisingly exhibits close phylogenetic relationships to some annelid intracellular globins. We have characterized the gene structure of A. ornata DHP to confirm assumptions about its homology with globins. It appears that it has the same intron position as in globin genes, suggesting a common ancestry with globins. In A. ornata, DHP may be a derived globin with an unusual enzymatic function.     

Expression of human protein phosphatase-1 in Saccharomyces cerevisiae highlights the role of phosphatase isoforms in regulating eukaryotic functions

Human (PP1) isoforms, PP1alpha, PP1beta, PP1gamma1, and PP1gamma2, differ in primary sequences at N and C termini that potentially bind cellular regulators and define their physiological functions. The GLC7 gene encodes the PP1 catalytic subunit with >80% sequence identity to human PP1 and is essential for viability of Saccharomyces cerevisiae. In yeast, Glc7p regulates glycogen and protein synthesis, actin cytoskeleton, gene expression, and cell division. We substituted human PP1 for Glc7p in yeast to investigate the ability of individual isoforms to catalyze Glc7p functions. S. cerevisiae expressing human PP1 isoforms were viable. PP1alpha-expressing yeast grew more rapidly than strains expressing other isoforms. On the other hand, PP1alpha-expressing yeast accumulated less glycogen than PP1beta-or PP1gamma1-expressing yeast. Yeast expressing human PP1 were indistinguishable from WT yeast in glucose derepression. However, unlike WT yeast, strains expressing human PP1 failed to sporulate. Analysis of chimeric PP1alpha/beta subunits highlighted a critical role for their unique N termini in defining PP1alpha and PP1beta functions in yeast. Biochemical studies established that the differing association of PP1 isoforms with the yeast glycogen-targeting subunit, Gac1p, accounted for their differences in glycogen synthesis. In contrast to human PP1 expressed in Escherichia coli, enzymes expressed in yeast displayed in vitro biochemical properties closely resembling PP1 from mammalian tissues. Thus, PP1 expression in yeast should facilitate future structure-function studies of this protein serine/threonine phosphatase.     

The evolution and functional diversification of animal microRNA genes

microRNAs （miRNAs） are an abundant class of-22 nucleotide （nt） regulatory RNAs that are pervasive in higher eukaryotic genomes. In order to fully understand their prominence in genomes, it is necessary to elucidate the molecular mechanisms that can diversify miRNA activities. In this review, we describe some of the many strategies that allow novel miRNA functions to emerge, with particular emphasis on how miRNA genes evolve in animals. These mechanisms include changes in their sequence, processing, or expression pattern; acquisition of miRNA^＊ functionality or antisense processing; and de novo gene birth. The facility and versatility of miRNAs to evolve and change likely underlies how they have become dominant constituents of higher genomes.     

Ⅰ型蛋白磷酸酶研究进展

Ⅰ型蛋白磷酸酶(PP1)属丝/苏氨酸磷酸酶的一种,在生物体中广泛存在,参与调节多种重要的生理功能,包括转录、翻译、代谢、细胞生长及分化等.PP1分子结构表面的3个凹槽及β 12-β 13 Loop环结构,它在底物与抑制剂的结合方面起决定作用.近期研究发现,Loop环结构除了是抑制剂的结合部位之外,对整个酶分子的结构和性质都起重要作用.功能研究也证明PP1还参与HIV-1转录过程的调节,并且与老年性痴呆等多种疾病密切相关.主要对PP1的组织分布、分子结构、酶学特性、催化机制以及生物学功能等方面进行了相应的综述.     

Conservation and diversification of Msx protein in metazoan evolution

Msx (/msh) family genes encode homeodomain (HD) proteins that control ontogeny in many animal species. We compared the structures of Msx genes from a wide range of Metazoa (Porifera, Cnidaria, Nematoda, Arthropoda, Tardigrada, Platyhelminthes, Mollusca, Brachiopoda, Annelida, Echiura, Echinodermata, Hemichordata, and Chordata) to gain an understanding of the role of these genes in phylogeny. Exon-intron boundary analysis suggested that the position of the intron located N-terminally to the HDs was widely conserved in all the genes examined, including those of cnidarians. Amino acid (aa) sequence comparison revealed 3 new evolutionarily conserved domains, as well as very strong conservation of the HDs. Two of the three domains were associated with Groucho-like protein binding in both a vertebrate and a cnidarian Msx homolog, suggesting that the interaction between Groucho-like proteins and Msx proteins was established in eumetazoan ancestors. Pairwise comparison among the collected HDs and their C-flanking aa sequences revealed that the degree of sequence conservation varied depending on the animal taxa from which the sequences were derived. Highly conserved Msx genes were identified in the Vertebrata, Cephalochordata, Hemichordata, Echinodermata, Mollusca, Brachiopoda, and Anthozoa. The wide distribution of the conserved sequences in the animal phylogenetic tree suggested that metazoan ancestors had already acquired a set of conserved domains of the current Msx family genes. Interestingly, although strongly conserved sequences were recovered from the Vertebrata, Cephalochordata, and Anthozoa, the sequences from the Urochordata and Hydrozoa showed weak conservation. Because the Vertebrata-Cephalochordata-Urochordata and Anthozoa-Hydrozoa represent sister groups in the Chordata and Cnidaria, respectively, Msx sequence diversification may have occurred differentially in the course of evolution. We speculate that selective loss of the conserved domains in Msx family proteins contributed to the diversification of animal body organization.     

Combinatorial control of protein phosphatase-1.

The catalytic subunit of the type 1 Ser/Thr protein phosphatases (PP1) can interact with many different regulatory (R) subunits. These R subunits function as activity-modulators, targeting subunits and/or substrates. The specificity of the R subunits can be accounted for by their interaction with specific subsets of binding pockets on the catalytic subunit and by the presence of subcellular targeting sequences. Hormones, growth factors and metabolites control the function of PP1 holoenzymes mainly by modulating the interaction of the subunits.     

Lessons from the deep: mechanisms behind diversification of eukaryotic protein complexes

Genetic variation is the major mechanism behind adaptation and evolutionary change. As most proteins operate through interactions with other proteins, changes in protein complex composition and subunit sequence provide potentially new functions. Comparative genomics can reveal expansions, losses and sequence divergence within protein-coding genes, but in silico analysis cannot detect subunit substitutions or replacements of entire protein complexes. Insights into these fundamental evolutionary processes require broad and extensive comparative analyses, from both in silico and experimental evidence. Here, we combine data from both approaches and consider the gamut of possible protein complex compositional changes that arise during evolution, citing examples of complete conservation to partial and total replacement by functional analogues. We focus in part on complexes in trypanosomes as they represent one of the better studied non-animal/non-fungal lineages, but extend insights across the eukaryotes by extensive comparative genomic analysis. We argue that gene loss plays an important role in diversification of protein complexes and hence enhancement of eukaryotic diversity.     

Heparin inhibits the activity of protein phosphatase-1

Heparin inhibited the dephosphorylation of rabbit skeletal muscle or liver phosphorylase a by protein phosphatase-1. Other glycosaminoglycans (chondroitin sulfates) and their constituents were found to be without effect. The chromatography of a partially purified phosphatase preparation on heparin-Sepharose CL-6B resulted in a fraction that did not bind to the matrix and its activity was not inhibited by heparin or inhibitor-1. The phosphatase bound to heparin-Sepharose was eluted by 0.2 M NaCl and was inhibited by heparin or inhibitor-1.     

Purification and characterization of T cell protein tyrosine phosphatase reveals significant functional homology to protein tyrosine phosphatase-1B

We have developed a protocol for rapid purification of T cell protein tyrosine phosphatase (TCPTP) and the structurally related protein tyrosine phosphatase-1B (PTP-1B) from bacterial cells. The pH profile for TCPTP was bell-shaped with an optimum of 5.5. The catalytic domain and full-length versions of TCPTP bound a potent inhibitor with affinities similar to those of PTP-1B. The K(m) values for the catalytic domains of TCPTP and PTP-1B increased with increasing ionic strength, whereas the k(cat) values remained unchanged. Arrhenius plots revealed that TCPTP and PTP-1B possess similar activation energies of 25.3+/-1.2 and 18.4+/-3.0 kJ/mol, respectively. Increasing solvent microviscosity (up to 40% (w/v) sucrose) did not affect k(cat)/K(m) of either enzyme. However, high sucrose concentrations protected both enzymes from thermal inactivation. These studies show that, although they share a 72% amino acid sequence identity within their catalytic domains, TCPTP and PTP-1B are functionally very similar in vitro.     

Radiation and functional diversification of alpha keratins during early vertebrate evolution

The conquest of land was arguably one of the most fundamental ecological transitions in vertebrates and entailed significant changes in skin structure and appendages to cope with the new environment. In extant tetrapods, the rigidity of the integument is largely created by type I and type II keratins, which are structural proteins essential in forming a strong cytoplasmic network. It is expected that such proteins have undergone fundamental changes in both stem and crown tetrapods. Here, we integrate genomic, phylogenetic, and expression data in a comprehensive study on the early evolution and functional diversification of tetrapod keratins. Our analyses reveal that all type I and type II tetrapod keratins evolved from only two genes that were present in the ancestor of extant vertebrates. Subsequently, the water-to-land transition in the stem lineage of tetrapods was associated with a major radiation and functional diversification of keratin genes. These duplications acquired functions that serve rigidity in integumental hard structures and were the prime for subsequent independent keratin diversification in tetrapod lineages.     

Classification and functional annotation of eukaryotic protein kinases

Reversible protein phosphorylation by protein kinases and phosphatases is a ubiquitous signaling mechanism in all eukaryotic cells. A multilevel hidden Markov model library is presented which is able to classify protein kinases into one of 12 families, with a misclassification rate of zero on the characterized kinomes of H. sapiens, M. musculus, D. melanogaster, C. elegans, S. cerevisiae, D. discoideum, and P. falciparum. The Library is shown to outperform BLASTP and a general Pfam hidden Markov model of the kinase catalytic domain in the retrieval and family-level classification of protein kinases. The application of the Library to the 38 unclassified kinases of yeast enriches the yeast kinome in protein kinases of the families AGC (5), CAMK (17), CMGC (4), and STE (1), thereby raising the family-level classification of yeast conventional protein kinases from 66.96 to 90.43%. The application of the Library to 21 eukaryotic genomes shows seven families (AGC, CAMK, CK1, CMGC, STE, PIKK, and RIO) to be present in all genomes analyzed, and so is likely to be essential to eukaryotes. Putative tyrosine kinases (TKs) are found in the plants A. thaliana (2), O. sativa ssp. Indica (6), and O. sativa ssp. Japonica (7), and in the amoeba E. histolytica (7). To our knowledge, TKs have not been predicted in plants before. This also suggests that a primitive set of TKs might have predated the radiation of eukaryotes. Putative tyrosine kinase-like kinases (TKLs) are found in the fungi C. neoformans (2), P. chrysosporium (4), in the Apicomplexans C. hominis (4), P. yoelii (4), and P. falciparum (6), the amoeba E. histolytica (109), and the alga T. pseudonana (6). TKLs are found to be abundant in plants (776 in A. thaliana, 1010 in O. sativa ssp. Indica, and 969 in O. sativa ssp. Japonica). TKLs might have predated the radiation of eukaryotes too and have been lost secondarily from some fungi. The application of the Library facilitates the annotation of kinomes and has provided novel insights on the early evolution and subsequent adaptations of the various protein kinase families in eukaryotes.     

Strong functional patterns in the evolution of eukaryotic genomes revealed by the reconstruction of ancestral protein domain repertoires

Background  

Genome size and complexity, as measured by the number of genes or protein domains, is remarkably similar in most extant eukaryotes and generally exhibits no correlation with their morphological complexity. Underlying trends in the evolution of the functional content and capabilities of different eukaryotic genomes might be hidden by simultaneous gains and losses of genes.     

The protein phosphatases involved in cellular regulation. Influence of polyamines on the activities of protein phosphatase-1 and protein phosphatase-2A

The effects of polyamines on the oligomeric forms of protein phosphatase-1 (1G), protein phosphatase-2A (2A0, 2A1 and 2A2) and their free catalytic subunits (1C and 2AC) has been studied using homogeneous enzymes isolated from rabbit skeletal muscle. Spermine increased the activity of protein phosphatase-2A towards eight of nine substrates tested. Half-maximal activation was observed at 0.2 mM with optimal effects at 1-2 mM. Above 2 mM, spermine became inhibitory. The most impressive activation of protein phosphatase-2A was obtained with glycogen synthase, especially when phosphorylated at sites-3 (8-15-fold with protein phosphatase-2A1) and phenylalanine hydroxylase (6-7-fold with protein phosphatase-2A1) as substrates. Activation of protein phosphatases 2A0, 2A1 and 2A2 was greater than that observed with 2AC. Spermine was a more potent activator than spermidine, while putrescine had only a small effect. Qualitatively similar results were obtained with five other substrates, although maximal activation was much less (1.3-3-fold with protein phosphatase-2A1). The rate of dephosphorylation of glycogen phosphorylase was decreased by spermine, inhibition being more pronounced with protein phosphatase-2AC than with 2A0, 2A1 and 2A2. Spermine (I50 = 0.1 mM with protein phosphatase-2AC) was a more potent inhibitor than spermidine (I50 = 0.9 mM) or putrescine (I50 = 8 mM). Partially purified preparations of protein phosphatases-2A0, 2A1 and 2A2 from from rat liver were affected by spermine in a similar manner to the homogeneous enzymes from rabbit skeletal muscle. Spermine did not activate protein phosphatase-1 to the same extent as protein phosphatase-2A. Greatest stimulation (2.5-fold) was again observed with glycogen synthase labelled in sites-3, with half-maximal activation at 0.2 mM and optimal effects at 1-2 mM spermine. Spermine was a much more effective stimulator than spermidine, while putrescine was ineffective. Very similar results were obtained with protein phosphatases 1G and 1C. With four other substrates maximal activation by spermine was less than 1.5-fold, while the dephosphorylation of glycogen synthase (labelled in site-2), phosphorylase kinase, pyruvate kinase and glycogen phosphorylase were inhibited. Spermine (I50 = 0.04 mM) was a more potent inhibitor of the dephosphorylation of glycogen phosphorylase than spermidine (I50 = 0.9 mM) or putrescine (I50 = 9 mM).(ABSTRACT TRUNCATED AT 400 WORDS)     

Determinants of the nucleolar targeting of protein phosphatase-1

The ubiquitously expressed protein Ser/Thr phosphatase-1 isoforms PP1alpha, PP1beta and PP1gamma1 are dynamically targeted to distinct, but overlapping cellular compartments by associated proteins. Within the nucleus of HeLa cells, EGFP-tagged PP1gamma1 and PP1beta were predominantly targeted to the nucleoli, while PP1alpha showed a more diffuse distribution. Using PP1 chimaeras and point mutants we show here that a single N-terminal residue, i.e., Gln20 for PP1alpha, Arg19 for PP1beta and Arg20 for PP1gamma1 accounts for their distinct subnuclear distribution. Our data also suggest that the N-terminus of PP1beta and PP1gamma1 harbours an interaction site for one or more nucleolar interactors.     

Identification of residues in glutathione transferase capable of driving functional diversification in evolution. A novel approach to protein redesign

Evolution of protein function can be driven by positive selection of advantageous nonsynonymous codon mutations that arise following gene duplication. By observing the presence and degree of site-specific positive selection for change between divergent paralogs, residue positions responsible for functional changes can be identified. We applied this analysis to genes encoding Mu class glutathione transferases, which differ widely in substrate specificities. Approximately 3% of the amino acid residue positions, both near to and distant from the active site, are under statistically significant positive selection for change. Relevant human glutathione transferase (GST) M1-1 and GST M2-2 codons were mutated. A chemically conservative threonine to serine mutation in GST M2-2 elicited a 1,000-fold increase in specific activity with the GST M1-1-specific substrate trans-stilbene oxide and a 30-fold increase with the alternative epoxide substrates styrene oxide and nitrophenyl glycidol. The reverse mutation in GST M1-1 resulted in reciprocal decreases in activity. Thus, identification of hypervariable codon positions can be a powerful aid in the redesign of protein function, lessening the requirement for extensive mutagenesis or structural knowledge and sometimes suggesting mutations that would otherwise be considered functionally conservative.