The complete DNA sequence of the mitochondrial genome of Physarum polycephalum

The complete sequence of the mitochondrial DNA (mtDNA) of the true slime mold Physarun polycephalum has been determined. The mtDNA is a circular 62,862-bp molecule with an A+T content of 74.1%. A search with the program BLAST X identified the protein-coding regions. The mitochondrial genome of P. polycephalum was predicted to contain genes coding for 12 known proteins [for three cytochrome c oxidase subunits, apocytochrome b, two F1Fo-ATPase subunits, five NADH dehydrogenase (nad) subunits, and one ribosomal protein], two rRNA genes, and five tRNA genes. However, the predicted ORFs are not all in the same frame, because mitochondrial RNA in P. polycephalum undergoes RNA editing to produce functional RNAs. The nucleotide sequence of an nad7 cDNA showed that 51 nucleotides were inserted at 46 sites in the mRNA. No guide RNA-like sequences were observed in the mtDNA of P. polycephalum. Comparison with reported Physarum mtDNA sequences suggested that sites of RNA editing vary among strains. In the Physarum mtDNA, 20 ORFs of over 300 nucleotides were found and ORFs 14 19 are transcribed.     

Primary structure of profilins from two species of Echinoidea and Physarum polycephalum

Profilin is a small G-actin-binding protein, the amino acid sequence of which was previously reported for calf, human, Acanthamoeba and yeast. Here the amino acid sequences of three profilins obtained from eggs of two species of Echinoidea, Clypeaster japonicus (order, Clypeasteroida) and Anthocidaris crassispina (order, Echinoida), and plasmodium of Physarum polycephalum were determined. Two echinoid profilins were composed of 139 amino acid residues, N-termini were acylated and the molecular mass was calculated to be 14.6 kDa, slightly larger than that of 13 kDa estimated by SDS/PAGE [Mabuchi, I. & Hosoya, H. (1982) Biomed. Res. 3, 465-476]. On the other hand, Physarum profilin was composed of 124 amino acid residues, the N-terminus was acylated, and the calculated molecular mass was 13132 Da. The sequences of C. japonicus and A. crassispina profilins were homologous (84% identical). However, the similarity of these profilins with those form other organisms was low. The sequence of Physarum profilin was homologous with Acanthamoeba profilin isoforms (51% identical) and with yeast profilin (42% identical), but not with other profilins. The relatively conservative sequence of profilins from yeast, Physarum, Acanthamoeba, echinoid eggs and mammalian cells was found in the N-terminal region, which was suggested to be a common actin-binding region. The C-terminal region was also conserved, although to a lesser extent than the N-terminal region.     

Refined solution structure of human profilin I.

Profilin is a ubiquitous eukaryotic protein that binds to both cytosolic actin and the phospholipid phosphatidylinositol-4,5-bisphosphate. These dual competitive binding capabilities of profilin suggest that profilin serves as a link between the phosphatidyl inositol cycle and actin polymerization, and thus profilin may be an essential component in the signaling pathway leading to cytoskeletal rearrangement. The refined three-dimensional solution structure of human profilin I has been determined using multidimensional heteronuclear NMR spectroscopy. Twenty structures were selected to represent the solution conformational ensemble. This ensemble of structures has root-mean-square distance deviations from the mean structure of 0.58 A for the backbone atoms and 0.98 A for all non-hydrogen atoms. Comparison of the solution structure of human profilin to the crystal structure of bovine profilin reveals that, although profilin adopts essentially identical conformations in both states, the solution structure is more compact than the crystal structure. Interestingly, the regions that show the most structural diversity are located at or near the actin-binding site of profilin. We suggest that structural differences are reflective of dynamical properties of profilin that facilitate favorable interactions with actin. The global folding pattern of human profilin also closely resembles that of Acanthamoeba profilin I, reflective of the 22% sequence identity and approximately 45% sequence similarity between these two proteins.     

Profilin is essential for tip growth in the moss Physcomitrella patens

The actin cytoskeleton is critical for tip growth in plants. Profilin is the main monomer actin binding protein in plant cells. The moss Physcomitrella patens has three profilin genes, which are monophyletic, suggesting a single ancestor for plant profilins. Here, we used RNA interference (RNAi) to determine the loss-of-function phenotype of profilin. Reduction of profilin leads to a complete loss of tip growth and a partial inhibition of cell division, resulting in plants with small rounded cells and fewer cells. We silenced all profilins by targeting their 3' untranslated region sequences, enabling complementation analyses by expression of profilin coding sequences. We show that any moss or a lily (Lilium longiflorum) profilin support tip growth. Profilin with a mutation in its actin binding site is unable to rescue profilin RNAi, while a mutation in the poly-l-proline binding site weakly rescues. We show that moss tip growing cells contain a prominent subapical cortical F-actin structure composed of parallel actin cables. Cells lacking profilin lose this structure; instead, their F-actin is disorganized and forms polarized cortical patches. Plants expressing the actin and poly-l-proline binding mutants exhibited similar F-actin disorganization. These results demonstrate that profilin and its binding to actin are essential for tip growth. Additionally, profilin is not needed for formation of F-actin, but profilin and its interactions with actin and poly-l-proline ligands are required to properly organize F-actin.     

Profilin promotes barbed-end actin filament assembly without lowering the critical concentration

The mechanism of profilin-promoted actin polymerization has been systematically reinvestigated. Rates of barbed-end elongation onto Spectrin.4.1.Actin seeds were measured by right angle light scattering to avoid confounding effects of pyrenyl-actin, and KINSIM was used to analyze elongation progress curves. Without thymosin-beta4, both actin and Profilin.Actin (P.A) are competent in barbed-end polymerization, and kinetic simulations yielded the same bimolecular rate constant ( approximately 10 x 10(6) M(-1) s(-1)) for actin monomer or Profilin.Actin. When measured in the absence of profilin, actin assembly curves over a 0.7-4 microM thymosin-beta4 concentration range fit a simple monomer sequestering model (1 microM K(D) for Thymosin-beta4.Actin). The corresponding constant for thymosin-beta4.pyrenyl-Actin, however, was significantly higher ( approximately 9-10 microM), suggesting that the fluorophore markedly weakens binding to thymosin-beta4. With solutions of actin (2 microM) and thymosin-beta4 (2 or 4 microM), the barbed-end assembly rate rose with increasing profilin concentration (0.7-2 microM). Actin assembly in presence of thymosin-beta4 and profilin fit a simple thermodynamic energy cycle, thereby disproving an earlier claim (D. Pantaloni and M.-F. Carlier (1993) Cell 75, 1007-1014) that profilin promotes nonequilibrium filament assembly by accelerating hydrolysis of filament-bound ATP. Our findings indicate that profilin serves as a polymerization catalyst that captures actin monomers from Thymosin-beta4.Actin and ushers actin as a Profilin.Actin complex onto growing barbed filament ends.     

Mapping of a Physarum chromosomal origin of replication tightly linked to a developmentally-regulated profilin gene.

We compared the pattern of replication of two cell-type specific profilin genes in one developmental stage of the slime mold Physarum polycephalum. Taking advantage of the natural synchrony of S-phase within the plasmodium, we established that the actively transcribed profilin P gene is tightly linked to a chromosomal replication origin and is replicated at the onset of S-phase. In contrast, the inactive profilin A gene is not associated with a replication origin and it is duplicated in mid S-phase. Mapping by two-dimensional gel electrophoresis defines a short DNA fragment in the proximal upstream region of the profilin P gene from which bidirectional replication is initiated. We further provide an estimate of the kinetics of elongation of the replicon and demonstrate that the 2 alleles of the profilin P gene are coordinately replicated. All these results were obtained on total DNA preparations extracted from untreated cells. They provide a strong evidence for site specific initiation of DNA replication in Physarum.     

Two adenovirus mRNAs have a common 5′ terminal leader sequence encoded at least 10 kb upstream from their main coding regions

The messenger RNAs encoding two late adenovirus serotype 2 (Ad2) proteins, fiber and 100K, were purified by hybridization to restriction endonuclease fragments of Ad2 DNA followed by electrophoresis on polyacrylamide gels containing 98% formamide. The 5′ terminal oligonucleotides generated by RNAase T1 digestion of the messengers were selected by dihydroxyboryl-cellulose chromatography. Both mRNAs gave an identical 5′-undecanucleotide with the general structure 7mG^5′ppp^5′A^mC^(m)U(C₄,U₃)G. This undecanucleotide could be removed by mild RNAase treatment from the mRNA after hybridization to DNA fragments containing the main coding sequence of the messenger. In contrast, a small region defined by Bal I-E (14.7–21) protects this undecanucleotide from RNase. A second region contained within both Hind III-B (17–31.5) and Hpa I-F (25.5–27.9), although unable to protect the undecanucleotide, hybridizes to both fiber and 100K mRNAs and protects a similar sequence of 100–150 nucleotides. These observations suggest that both mRNAs contain a long common sequence, complementary to at least two different sites on the Ad2 genome remote from the start of these two genes. The implications of these findings are discussed, and a general mechanism is presented for the biosynthesis of mRNAs from larger precursor molecules, based on intramolecular ligation.     

Insertional editing in mitochondria of Physarum

RNA produced from a number of genes on the mitochondrial (mt) DNA of Physarum polycephalum have nucleotides inserted at specific sites in their sequence. These insertions are spaced at approximately 25 nucleotide intervals and create open reading frames in mRNA and functional structure in tRNAs and rRNAs. Although most of the insertions at a site are single cytidines; single uridines and certain dinucleotides containing adenosine and guanosine as well as cytidine and uridine are also occasionally inserted at certain sites. This mixed nucleotide insertional RNA editing is unique among currently characterized editing systems.     

The envelope-associated 22K protein of human respiratory syncytial virus: nucleotide sequence of the mRNA and a related polytranscript

We recently determined that respiratory syncytial virus (strain A2) encodes a fourth unique envelope-associated virion protein that has molecular weight of approximately 24,000, as estimated by gel electrophoresis. The nucleotide sequence of the mRNA encoding this novel protein has now been determined from five cDNA clones, including three that contain the complete mRNA sequence. The complete mRNA sequence is 957 nucleotides, exclusive of polyadenylate, and contains two partially overlapping open reading frames. The 5'-proximal open reading frame is favored for utilization by the criteria of the location and sequence of its translational start site. Furthermore, the calculated molecular weight of the encoded protein, 22,153, is in agreement with the previous estimate of 24,000 for the authentic protein identified by hybrid selection and in vitro translation. The sequence of the predicted protein, now designated the 22K protein, contains 194 amino acids, is relatively hydrophilic, and appears to be the most basic of the respiratory syncytial virus proteins. The mRNA also contains a second, internal open reading frame which would encode a protein of 90 amino acids. However, no evidence for this translation product is known. The first nine nucleotides in the mRNA sequence, 5'-GGGGCAAAU, are identical to the conserved sequence identified previously at the 5' termini of seven other respiratory syncytial viral mRNAs; the sequence at the 3' end of the 22K mRNA, 5'. . . AGUUAUUU-polyadenylate, contains the elements of the previously identified 3'-terminal consensus sequence for respiratory syncytial virus mRNAs, AGUUAA(N)1-4-polyadenylate (P. L. Collins, Y. T. Huang, and G. W. Wertz, Proc. Natl. Acad. Sci. U.S.A. 81:7683-7687). In addition, we present and describe the intergenic sequence of a dicistronic RNA derived from readthrough of the F and 22K protein genes.     

Profilin binding to sub-micellar concentrations of phosphatidylinositol (4,5) bisphosphate and phosphatidylinositol (3,4,5) trisphosphate

Profilin is a small (12-15 kDa) actin binding protein which promotes filament turnover. Profilin is also involved in the signaling pathway linking receptors in the cell membrane to the microfilament system within the cell. Profilin is thought to play critical roles in this signaling pathway through its interaction with phosphatidylinositol 4,5-bisphosphate [PI(4,5)P(2)] and phosphatidylinositol 3,4,5-trisphosphate [PI(3,4,5)P(3)] (P.J. Lu, W.R. Shieh, S.G. Rhee, H.L. Yin, C.S. Chen, Lipid products of phosphoinositide 3-kinase bind human profilin with high affinity, Biochemistry 35 (1996) 14027-14034). To date, profilin's interaction with polyphosphoinositides (PPI) has only been studied in micelles or small vesicles. Profilin binds with high affinity to small clusters of PI(4,5)P(2) molecules. In this work, we investigated the interactions of profilin with sub-micellar concentrations of PI(4,5)P(2) and PI(3,4,5)P(3). Fluorescence anisotropy was used to determine the relevant dissociation constants for binding of sub-micellar concentrations of fluorescently labeled PPI lipids to profilin and we show that these are significantly different from those determined for profilin interaction with micelles or small vesicles. We also show that profilin binds more tightly to sub-micellar concentrations of PI(3,4,5)P(3) (K(D)=720 microM) than to sub-micellar concentrations of PI(4,5)P(2) (K(D)=985 microM). Despite the low affinity for sub-micellar concentration of PI(4,5)P(2), profilin was shown to bind to giant unilamellar vesicles in presence of 0.5% mole fraction of PI(4,5)P(2) The implications of these findings are discussed.     

Mouse glutamine synthetase is encoded by a single gene that can be expressed in a localized fashion

Two mouse glutamine synthetase (GSase) cDNAs were cloned that correspond to the 2.8 kb and 1.4 kb mRNA species found in many mouse tissues (1 kb = 10(3) base-pairs). There is a sequence homology of about 90% to other mammalian GSase cDNAs in the coding region. A 2.1 kb mRNA can be discerned in fat tissue, the most abundant source of GSase mRNA. Three genomic clones G4, G21 and G2 contain GSase sequences. By several criteria G21 and G2 are pseudogenes, while G4 is a functional gene composed of seven exons and six introns. Primer extension, RNase protection and Northern analysis provide evidence that all tissues use the same major RNA start site and the different-sized mRNAs are due to the usage of two different poly(A) sites, neither of which has the consensus AAUAAA sequence. When tested by transfection into Hep G2 human hepatoma cells the G4 promoter can produce correctly initiated mRNA with only 350 base-pairs of 5' regulatory sequences. A major interest in GSase expression is its restriction to pericentral hepatocytes in adult liver. In this paper we show by in situ hybridization that GSase mRNA is only found in glial cells in the adult brain and in proximal tubular epithelium of the kidney. Coupled with the earlier demonstration of expression of GSase only in pericentral hepatocytes, it is clear that this gene is regulated by position-specific signals in many cell types.