Fate of the 63-kDa periplasmic protein of the infectious form of the endonuclear symbiotic bacterium Holospora obtusa during the infection process

Holospora obtusa is a macronucleus-specific endosymbiotic bacterium of the ciliate Paramecium caudatum. We report the secretion of a 63-kDa periplasmic protein of an infectious form of the bacterium into the macronucleus of its host. Indirect immunofluorescence microscopy with five monoclonal antibodies against the 63-kDa protein demonstrated that, soon after the bacterial invasion into the host macronucleus, the protein was detected in the infected macronucleus and that levels of the protein increased dramatically within one day of infection. The use of inhibitors for host and bacterial protein synthesis illustrated that, in early infection of H. obtusa, not only the pre-existing but also a newly synthesized 63-kDa protein was secreted into the host macronucleus. A partial amino acid sequence of the protein was determined, and a gene encoding the 63-kDa protein was cloned. The deduced amino acid sequence shows that this protein is a novel protein.     

Purification of the putative import-receptor for the precursor of the mitochondrial protein

The receptor protein for the mitochondrial protein precursor synthesized in the cytosol was extensively purified from the mitochondrial membrane fraction by affinity column chromatography using a synthetic peptide containing the extrapeptide of ornithine aminotransferase as a ligand. The purified fraction contained two major proteins with molecular masses of 52 and 29 kDa. Of these proteins, only the 29 kDa protein bound to the extrapeptide of ornithine aminotransferase. Furthermore, anti-29 kDa protein Fab fragments inhibited the import of pre-ornithine aminotransferase into mitochondria, suggesting that the 29 kDa protein plays an essential role in the process of import of the mitochondrial protein precursor.     

Cross-linking of the proteins in the outer membrane of Escherichia coli.

1. The organization of the proteins in the outer membrane of Escherichia coli was examined by the use of cross-linking agents and two-dimensional sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Treatment of protein A-peptidoglycan complexes with dithiobis(succinimidyl propionate) or glutaraldehyde produced the dimer, trimer, and higher oligomers of protein A. Both forms of this protein, proteins A1 and A2, produced similar cross-linking products. No cross-linking of protein A to the peptidoglycan was detected. 2. The proteins of the isolated outer membrane varied in their ease of cross-linking. The heat-modifiable protein, protein B, was readily cross-linked to give high molecular weight oligomers, while protein A formed mainly the dimer and trimer under the same conditions. The pronase resistant fragment, protein Bp, derived from protein B was not readily cross-linked. No linkage of protein A to protein B was detected. 3. Cross-linking of cell wall preparations, consisting of the outer membrane and peptidoglycan, showed that protein B and the free form of the lipoprotein, protein F, could be linked to the peptidoglycan. A dimer of protein F, and protein F linked to protein B, were detected. 4. These results suggest that specific protein-protein interactions occur in the outer membrane.     

Biochemical basis of the temperature-inducible constitutive protease activity of the RecA441 protein of Escherichia coli

We compared the biochemical properties of the RecA441 protein to those of the wild-type RecA protein in an effort to account for the constitutive protease activity observed in recA441 strains. The two RecA proteins have similar properties in the absence of single-stranded DNA binding protein (SSB protein), and the differences that do exist shed little light on the temperature-inducible phenotype observed in recA441 strains. In contrast, several biochemical differences are apparent when the two proteins are compared in the presence of SSB protein, and these are conducive to a hypothesis that explains the temperature-sensitive behavior observed in these strains. We find that both the single-stranded DNA (ssDNA)-dependent ATPase and LexA-protease activities of RecA441 protein are more resistant to inhibition by SSB protein than are the activities of the wild-type protein. Additionally, the RecA441 protein is more capable of using ssDNA that has been precoated with SSB protein as a substrate for ATPase and protease activities, implying that RecA441 protein is more proficient at displacing SSB protein from ssDNA. The enhanced SSB protein displacement ability of the RecA441 protein is dependent on elevated temperature. These observations are consistent with the hypothesis that the RecA441 protein competes more efficiently with SSB protein for limited ssDNA sites and can be activated to cleave repressors at elevated temperature by displacing SSB protein from the limited ssDNA that occurs naturally in Escherichia coli. Neither the ssDNA binding characteristics of the RecA441 protein nor the rate at which it transfers from one DNA molecule to another provides an explanation for its enhanced activities, leading us to conclude that kinetics of RecA441 protein association with DNA may be responsible for the properties of the RecA441 protein.     

Role of the deinhibitor protein in the interconversion of the ATP,Mg-dependent protein phosphatase

The small molecular weight (± 9,000) heat stable deinhibitor protein, isolated from dog liver, not only protects the multisubstrate protein phosphatase from inhibition by inhibitor-1 and the modulator protein. It prevents the conversion of the active enzyme to the ATP,Mg-dependent enzyme form brought about by the modulator protein, and also affects the activation of the ATP,Mg-dependent protein phosphatase, probably by stabilizing the enzyme in its active conformation during the reversible activation by protein kinase F_A. Therefore the deinhibitor protein could be an important factor in the process of glycogen synthesis, which requires glycogen synthase and phosphorylase as dephosphorylated enzymes.     

Identification of the inhibitor of the plasminogen activator as the major protein secreted by endothelial rat liver cells

Freshly isolated Kupffer and endothelial liver cells exhibit a rate of 'de novo' protein synthesis which is twice as high per mg cell protein as that of parenchymal liver cells and contribute significantly (7.5% and 5.9%, respectively) to total liver protein secretion. In parenchymal cells the main secretory protein is a 68 kDa protein (containing 19% fo the secreted radioactivity, presumably albumin). In Kupffer cells a 49 kDa protein contains 8% of the secreted radioactivity, while in endothelial liver cells a 55 kDa protein is the most prominent secretory protein (containing 11% of the secreted radioactivity). By aid of a specific antibody the 55 kDa protein was identified as the inhibitor of the plasminogen activator and in the liver this protein was only secreted by the endothelial cells.     

On the role of the N-terminus of the extrinsic 33 kDa protein of Photosystem II

The role of the N-terminus of the extrinsic 33 kDa protein of Photosystem II has been investigated by means of site-directed mutagenesis and cross-linking. Replacement of Asp-9 resulted in a dramatic increase in proteolytic sensitivity leading to the degradation of the protein forming a 31 kDa fragment with an undefined N-terminus. This fragment was unable to restore oxygen evolution. However, the variants of the 33 kDa protein which remained intact could reconstitute oxygen evolution as effectively as the wild-type protein. Cross-linking experiments with a water-soluble carbodiimide revealed that mutagenesis of residue D9 led to the disruption of an intramolecular salt bridge. Therefore we suggest that the N-terminus of the 33 kDa protein is necessary for maintaining the binding ability of the protein to Photosystem II but might not be involved in binding itself.     

Determinations of the DNA sequence of the mreB gene and of the gene products of the mre region that function in formation of the rod shape of Escherichia coli cells.

The 6.5-kilobase mre region at 71 min in the Escherichia coli chromosome map, where genes involved in formation of a rod-shaped cell form a gene cluster, was analyzed by in vivo protein synthesis in a maxicell system and by base sequencing of DNA. An open reading frame that may code for a protein with an Mr of about 37,000 on sodium dodecyl sulfate-polyacrylamide gels was found and was correlated with the mreB gene. N-terminal amino acid sequencing of the hybrid mreB-lacZ protein confirmed the production by mreB of a protein of 347 amino acid residues with a molecular weight of 36,958. The amino acid sequence of this protein deduced from the DNA sequence showed close similarity with that of a protein of the ftsA gene which is involved in cell division of E. coli. Three other contiguous genes that formed three proteins with Mrs of about 40,000, 22,000, and 51,000, respectively, were detected downstream of the mreB gene by in vivo protein synthesis. The mreB protein and some of these three proteins may function together in determination of cell shape.     

Biochemical properties of the Escherichia coli recA430 protein. Analysis of a mutation that affects the interaction of the ATP-recA protein complex with single-stranded DNA

The biochemical properties of the recA430 protein have been examined and compared to those of wild-type recA protein. We find that, while the recA430 protein possesses ssDNA-dependent rATP activity, this activity is inhibited by the Escherichia coli single-stranded DNA binding protein (SSB protein) under many conditions that enhance wild-type recA protein rATPase hydrolysis. Stimulation of rATPase activity by SSB protein is observed only at high concentrations of both rATP (greater than 1 mM) and recA430 protein (greater than 5 microM). In contrast, stimulation of ssDNA-dependent dATPase activity by SSB protein is less sensitive to protein and nucleotide concentration. Consistent with the nucleotide hydrolysis data, recA430 protein can carry out DNA strand exchange in the presence of either rATP or dATP. However, in the presence of rATP, both the rate and the extent of DNA strand exchange by recA430 protein are greatly reduced compared to wild-type recA protein and are sensitive to recA430 protein concentration. This reduction is presumably due to the inability of recA430 protein to compete with SSB protein for ssDNA binding sites under these conditions. The cleavage of lexA repressor protein by recA430 protein is also sensitive to the nucleotide cofactor present and is completely inhibited by SSB protein when rATP is the cofactor but not when dATP is used. Finally, the steady-state affinity and the rate of association of the recA430 protein-ssDNA complex are reduced, suggesting that the mutation affects the interaction of the ATP-bound form of recA protein with ssDNA. This alteration is the likely molecular defect responsible for inhibition of recA430 protein rATP-dependent function by SSB protein. The biochemical properties observed in the presence of dATP and SSB protein, i.e. the reduced levels of both DNA strand exchange activity and cleavage of lexA repressor protein, are consistent with the phenotypic behavior of recA430 mutations.     

Characterization of the helicase and primase activities of the 63-kDa component of the bacteriophage T7 gene 4 protein

Leading and lagging strand DNA synthesis at the replication fork of bacteriophage T7 DNA requires the helicase and primase activities of the gene 4 protein. Gene 4 protein consists of two colinear polypeptides of 56- and 63-kDa molecular mass. We have demonstrated previously that the 56-kDa protein possesses helicase but lacks primase activity (Bernstein, J. A., and Richardson, C. C. (1988) Proc. Natl. Acad. Sci. U.S.A. 85, 396-400). The 63-kDa gene 4 protein has now been purified from extracts of T7-infected cells. The preparation contains 5-10% contaminating 56-kDa protein, as shown by Western analysis using polyclonal antibodies to the purified 56-kDa protein. The 63-kDa protein catalyzes DNA-dependent dTTP hydrolysis and has helicase activity; both specific activities are similar to those determined for the 56-kDa protein. The 63-kDa protein efficiently synthesizes sequence-specific di-, tri-, and tetraribonucleotides and stimulates the elongation of tetraribonucleotides by T7 DNA polymerase. Although the 56-kDa protein alone lacks primase activity, it enhances the primase activity of the 63-kDa protein 4-fold. This stimulation can be accounted for by a similar increase in the amount of primers synthesized by the 63-kDa protein in the presence of the 56-kDa protein.     

Influence of the fermentative cross-seams on the structure of the microsomal membrane

In rat liver microsomes freezing with subsequent thawing led to irreversible redistribution of protein-lipid packing. This redistribution was detected by a change in the efficiency of energy transfer between protein aromatic groups of membrane protein and lipid-soluble fluorescent probe pyrene. Transglutaminase pretreatment of microsomes prevented the irreversible redistribution. The enzyme is shown to bind no more than 15 per cent of the whole membrane protein. This smaller part of the microsomal protein is supposed to play the decisive role in the movements of its remaining part.     

Influence of the N-terminal domain on the aggregation properties of the prion protein

Prion diseases appear to be caused by the aggregation of the cellular prion protein (PrP(C)) into an infectious form denoted PrP(Sc). The in vitro aggregation of the prion protein has been extensively investigated, yet many of these studies utilize truncated polypeptides. Because the C-terminal portion of PrP(Sc) is protease-resistant and retains infectivity, it is assumed that studies on this fragment are most relevant. The full-length protein can be distinguished from the truncated protein because it contains a largely structured, alpha-helical, C-terminal region in addition to an N terminus that is unstructured in the absence of metal ion binding. Herein, the in vitro aggregation of a truncated portion of the prion protein (PrP 90-231) and a full-length version (PrP 23-231) were compared. In each case, concentration-dependent aggregation was analyzed to discern whether it proceeds by a nucleation-dependent pathway. Both protein constructs appear to aggregate via a nucleated polymerization with a small nucleus size, yet the later steps differ. The full-length protein forms larger aggregates than the truncated protein, indicating that the N terminus may mediate higher-order aggregation processes. In addition, the N terminus has an influence on the assembly state of PrP before aggregation begins, causing the full-length protein to adopt several oligomeric forms in a neutral pH buffer. Our results emphasize the importance of studying the full-length protein in addition to the truncated forms for in vitro aggregation studies in order to make valid hypotheses about the mechanisms of prion aggregation and the distribution of aggregates in vivo.     

Leader peptidase catalyzes the release of exported proteins from the outer surface of the Escherichia coli plasma membrane

Leader peptidase cleaves the amino-terminal leader sequences of many secreted and membrane proteins. We have examined the function of leader peptidase by constructing an Escherichia coli strain where its synthesis is controlled by the arabinose B promoter. This strain requires arabinose for growth. When the synthesis of leader peptidase is repressed, protein precursors accumulate, including the precursors of M13 coat protein (an inner membrane protein), maltose binding protein (a periplasmic protein), and OmpA protein (an outer membrane protein). These precursors are translocated across the plasma membrane, as judged by their sensitivity to added proteinase K. However, pro-OmpA and pre-maltose binding protein are retained at the outer surface of the inner membrane. Thus, leader peptides anchor translocated pre-proteins to the outer surface of the plasma membrane and must be removed to allow their subsequent release into the periplasm or transit to the outer membrane.     

Renewal of opsin in the photoreceptor cells of the mosquito

Mosquito rhodopsin is a digitonin-soluble membrane protein of molecular weight 39,000 daltons, as determined by sodium dodecyl sulfate gel electrophoresis. The rhodopsin undergoes a spectral transition from R515-520 to M480 after orange illumination. The visual pigment apoprotein, opsin, is the major membrane protein in the eye. Protein synthesis in the photoreceptor cells occurs in the perinuclear cytoplasm and the newly made protein is transported to the rhabdom. Light adaptation increases the rate of turnover of this rhabdomal protein. The turnover of electrophoretically isolated opsin is also stimulated by light adaptation. The changes observed in protein metabolism biochemically, are consistent with previous morphological observations of photoreceptor membrane turnover. The results agree with the hypothesis that the newly synthesized rhabdomal protein is opsin.     

Proteolytic removal of the COOH terminus of the T4 gene 32 helix-destabilizing protein alters the T4 in vitro replication complex

The proteolytic removal of about 60 amino acids from the COOH terminus of the bacteriophage T4 helix-destabilizing protein (gene 32 protein) produces 32*I, a 27,000-dalton fragment which still binds tightly and cooperatively to single-stranded DNA. The substitution of 32*I protein for intact 32 protein in the seven-protein T4 replication complex results in dramatic changes in some of the reactions catalyzed by this in vitro DNA replication system, while leaving others largely unperturbed. 1. Like intact 32 protein, the 32*I protein promotes DNA synthesis by the DNA polymerase when the T4 polymerase accessory proteins (gene 44/62 and 45 proteins) are also present. The host helix-destabilizing protein (Escherichia coli ssb protein) cannot replace the 32I protein for this synthesis. 2. Unlike intact 32 protein, 32*I protein strongly inhibits DNA synthesis catalyzed by the T4 DNA polymerase alone on a primed single-stranded DNA template. 3. Unlike intact 32 protein, the 32*I protein strongly inhibits RNA primer synthesis catalyzed by the T4 gene 41 and 61 proteins and also reduces the efficiency of RNA primer utilization. As a result, de novo DNA chain starts are blocked completely in the complete T4 replication system, and no lagging strand DNA synthesis occurs. 4. The 32*I protein does not bind to either the T4 DNA polymerase or to the T4 gene 61 protein in the absence of DNA; these associations (detected with intact 32 protein) would therefore appear to be essential for the normal control of 32 protein activity, and to account at least in part for observations 2 and 3, above. We propose that the COOH-terminal domain of intact 32 protein functions to guide its interactions with the T4 DNA polymerase and the T4 gene 61 RNA-priming protein. When this domain is removed, as in 32*I protein, the helix destabilization induced by the protein is controlled inadequately, so that polymerizing enzymes tend to be displaced from the growing 3'-OH end of a polynucleotide chain and are thereby inhibited. Eukaryotic helix-destabilizing proteins may also have similar functional domains essential for the control of their activities.     

Studies on the subcellular localization of the membrane-bound fraction of intestinal calcium-binding protein

Sorbitol density gradient centrifugation applied to intestinal mucosa homogenates resulted in a complete separation of soluble calcium-binding protein from the bound fraction of calcium-binding protein, providing further documentation of the bound pool of calcium-binding protein. The peak of the bound calcium-binding protein was not associated with the major peaks of any of the markers used, but was associated with minor peaks of alkaline phosphatase, RNA, and glucose-6-phosphatase. Lack of association of bound calcium-binding protein with (Na⁺ + K⁺)-ATPase indicated that the bound calcium-binding protein is not on the basolateral membrane. Differential centrifugation fractionation indicated that the bound calcium-binding protein is not associated with nuclei or mitochondria. The bound calcium-binding protein also could not be detected in partially pyrified brush borders. Exclusion of the brush border and basolateral membranes as the location of the bound calcium-binding protein suggests an intracellular locate.     

Studies on the subcellular localization of the membrane-bound fraction of intestinal calcium-binding protein.

Sorbitol density gradient centrifugation applied to intestinal mucosa homogenates resulted in a complete separation of soluble calcium-binding protein from the bound fraction of calcium-binding protein, providing further documentation of the bound pool of calcium-binding protein. The peak of the bound calcium-binding protein was not associated with the major peaks of any of the markers used, but was associated with minor peaks of alkaline phosphatase, RNA, and glucose-6-phosphatase. Lack of association of bound calcium-binding protein with (Na+ + K+)-ATPase indicated that the bound calcium-binding protein is not on the basolateral membrane. Differential centrifugation fractionation indicated that the bound calcium-binding protein is not associated with nuclei or mitochondria. The bound calcium-binding protein also could not be detected in partially purified brush borders. Exclusion of the brush border and basolateral membranes as the location of the bound calcium-binding protein suggests an intracellular locale.     

Tracking the role of a star in the sky of the new millennium.

The steroidogenic acute regulatory protein is indispensable for the biosynthesis of steroid hormones. Steroidogenic acute regulatory protein mediates the rate-limiting step in steroidogenesis, the transfer of cholesterol from the outer mitochondrial membrane to the inner mitochondrial membrane where it is cleaved to pregnenolone. Its essential role in steroidogenesis was shown when it was discovered that mutations in the steroidogenic acute regulatory protein gene in humans cause the lipoid form of congenital adrenal hyperplasia, a potentially lethal disease resulting from an inability to synthesize steroids. Also, the steroidogenic acute regulatory protein null mouse has a phenotype that is essentially the same as that observed with human mutations. Studies on the regulation of the expression of the steroidogenic acute regulatory protein gene has enjoyed considerable progress, yet the complexity of this regulation indicates that much work remains. The mechanism whereby steroidogenic acute regulatory protein mediates the transfer of cholesterol to the inner mitochondrial membrane remains a mystery, but the recent solving of the structure of the cholesterol transferring domain of a steroidogenic acute regulatory protein homolog coupled with structure-function studies of steroidogenic acute regulatory protein in natural and synthetic membranes has allowed for at least two models to be proposed. This review will briefly attempt to summarize what is currently known about the regulation of the steroidogenic acute regulatory protein gene and its mechanism of action, fully understanding that in both areas considerable gaps in our knowledge remain.     

Determinants for membrane association and permeabilization of the coxsackievirus 2B protein and the identification of the Golgi complex as the target organelle

The 2B protein of enterovirus is responsible for the alterations in the permeability of secretory membranes and the plasma membrane in infected cells. The structural requirements for the membrane association and the subcellular localization of this essential virus protein, however, have not been defined. Here, we provide evidence that the 2B protein is an integral membrane protein in vivo that is predominantly localized at the Golgi complex upon individual expression. Addition of organelle-specific targeting signals to the 2B protein revealed that the Golgi localization is an absolute prerequisite for the ability of the protein to modify plasma membrane permeability. Expression of deletion mutants and heterologous proteins containing specific domains of the 2B protein demonstrated that each of the two hydrophobic regions could mediate membrane binding individually. However, the presence of both hydrophobic regions was required for the correct membrane association, efficient Golgi targeting, and the membrane-permeabilizing activity of the 2B protein, suggesting that the two hydrophobic regions are cooperatively involved in the formation of a membrane-integral complex. The formation of membrane-integral pores by the 2B protein in the Golgi complex and the possible mechanism by which a Golgi-localized virus protein modifies plasma membrane permeability are discussed.