Movement of the free catalytic subunit of cAMP-dependent protein kinase into and out of the nucleus can be explained by diffusion.

The catalytic (C) subunit of cyclic AMP (cAMP) dependent protein kinase (PKA) has previously been shown to enter and exit the nucleus of cells when intracellular cAMP is raised and lowered, respectively. To determine the mechanism of nuclear translocation, fluorescently labeled C subunit was injected into living REF52 fibroblasts either as free C subunit or in the form of holoenzyme (PKA) in which the catalytic and regulatory subunits were labeled with fluorescein and rhodamine, respectively. Quantification of nuclear and cytoplasmic fluorescence intensities revealed that free C subunit nuclear accumulation was most similar to that of macromolecules that diffuse into the nucleus. A glutathione S-transferase-C subunit fusion protein did not enter the nucleus following cytoplasmic microinjection. Puncturing the nuclear membrane did not decrease the nuclear concentration of C subunit, and C subunit entry into the nucleus did not appear to be saturable. Cooling or depleting cells of energy failed to block movement of C subunit into the nucleus. Photobleaching experiments showed that even after reaching equilibrium at high [cAMP], individual molecules of C subunit continued to leave the nucleus at approximately the same rate that they had originally entered. These results indicate that diffusion is sufficient to explain most aspects of C subunit subcellular localization.     

Assembly of the (Na+ + K+)-adenosine triphosphatase. Post-translational membrane integration of the alpha subunit

Guinea pig kidney poly(A+) RNA was translated in reticulocyte lysates and wheat germ extracts. Antibodies to the holoenzyme (Na/K-ATPase) immunoprecipitated only a 96,000-dalton product which was identified as the alpha subunit with a molecular weight that was indistinguishable from that of mature alpha subunit. To explore the possibility that the primary translational product is integrated as such into membranes, guinea pig kidney poly(A+) RNA was translated in reticulocyte lysates in the presence of dog pancreas microsomes; two immunoprecipitated products were detected, the 96,000-dalton alpha subunit and a 135,000-dalton new component that was integrated into the microsomal membrane since it was completely resistant to extraction with alkali. Addition of purified alpha subunit inhibited the binding of antibody to the 135,000-dalton product and extraction with urea-sodium dodecyl sulfate recovered the 96,000-dalton product, implying that the 135,000-dalton product was an alpha-chi dimer. Translation of size-fractionated poly(A+) RNA yielded evidence that the 135,000-dalton product is encoded in two separate mRNAs. The integration in vitro of the alpha subunit is, therefore, dependent on the co-translational integration into the membranes of a smaller peptide (35,000 to 40,000 daltons) which is presumably the beta subunit. Evidence was also obtained that this mechanism is present in vivo by isolation of mRNA alpha from free polysomes, as well as detection of the cytosolic form of the alpha subunit in pulse-chase experiments in MDCK cells.     

Changes of the quaternary structure of microvillus aminopeptidase in the membrane

Microvillus aminopeptidase (EC 3.4.11.2) is an enzyme with a molecular weight around 300 000. Normal preparations contain three different subunits (subunit A, Mr 162 000; subunit B, Mr 123 000; subunit C, Mr 61 000). The relationship between the three subunits was studied by immunoelectrophoresis using specific antibodies against individual denatured subunits and by densitometric scanning of polyacrylamide gels after separation of the three subunits. The results suggest that microvillus aminopeptidase initially appears in the membrane as a symmetric molecule built up to two identical A subunits. These subunits are then split into equimolar amounts of subunit B and subunit C by trypsin. Subunit B cannot generate subunit C but may be further degraded. The reaction sequence described is one which occurs in vivo. Treatment of purified aminopeptidase with trypsin increases the specific activity twofold. This phenomenon does not seem to be correlated to the generation of subunit B and subunit C or to the transformation of amphiphilic form into hydrophilic form.     

Both the p33 and p55 Subunits of the Helicobacter pylori VacA Toxin Are Targeted to Mammalian Mitochondria

Helicobacter pylori infection causes peptic ulcers and gastric cancer. A major toxin secreted by H. pylori is the bipartite vacuolating cytotoxin A, VacA. The toxin is believed to enter host cells as two subunits: the p55 subunit (55 kDa) and the p33 subunit (33 kDa). At the biochemical level, it has been shown that VacA forms through the assembly of large multimeric pores composed of both the p33 subunit and the p55 subunit in biological membranes. One of the major target organelles of VacA is the mitochondria. Since only the p33 subunit has been reported to be translocated into mitochondria and the p55 subunit is not imported, it has been contentious as to whether VacA assembles into pores in a mitochondrial membrane. Here we show the p55 protein is imported into the mitochondria along with the p33 protein subunit. The p33 subunit integrally associates with the mitochondrial inner membrane, and both the p33 subunit and the p55 subunit are exposed to the mitochondrial intermembrane space. Their colocalization suggests that they could reassemble and form a pore in the inner mitochondrial membrane.     

Cytochrome b is necessary for the assembly of subunit VII in the cytochrome b-c1 complex of yeast mitochondria

The synthesis and assembly of subunit VII, the Q-binding protein of the cytochrome b-c1 complex, into the inner mitochondrial membrane has been compared in wild-type yeast cells and in a mutant cell line lacking cytochrome b. Both immunoblotting and immunoprecipitation analysis with specific antiserum against subunit VII indicated that this subunit is not detectable in the mutant as compared to the wild-type mitochondria. However, labeling in vivo of the cytochrome b deficient yeast cells in the presence of the uncoupler carbonyl cyanide m-chlorophenylhydrazone clearly demonstrated that subunit VII was synthesized in the mutant cells to the same extent as in the wild-type cells. Incubation of subunit VII, synthesized in vitro in a reticulocyte lysate programmed with yeast RNA, with mitochondria isolated from both wild-type and cytochrome b deficient yeast cells revealed that the subunit VII was transported into the wild-type mitochondria into a compartment where it was resistant to digestion by exogenous proteinase K. By contrast, subunit VII was bound in lowered amounts to the cytochrome b deficient mitochondria where it remained sensitive to digestion by exogenous proteinase K, suggesting that the import of subunit VII may be impaired due to the lack of cytochrome b. Furthermore, subunit VII was synthesized both in vivo and in vitro with the same molecular mass as the mature form of this protein.     

Amino acid sequence of the human fibronectin receptor

The amino acid sequence deduced from cDNA of the human placental fibronectin receptor is reported. The receptor is composed of two subunits: an alpha subunit of 1,008 amino acids which is processed into two polypeptides disulfide bonded to one another, and a beta subunit of 778 amino acids. Each subunit has near its COOH terminus a hydrophobic segment. This and other sequence features suggest a structure for the receptor in which the hydrophobic segments serve as transmembrane domains anchoring each subunit to the membrane and dividing each into a large ectodomain and a short cytoplasmic domain. The alpha subunit ectodomain has five sequence elements homologous to consensus Ca2+-binding sites of several calcium-binding proteins, and the beta subunit contains a fourfold repeat strikingly rich in cysteine. The alpha subunit sequence is 46% homologous to the alpha subunit of the vitronectin receptor. The beta subunit is 44% homologous to the human platelet adhesion receptor subunit IIIa and 47% homologous to a leukocyte adhesion receptor beta subunit. The high degree of homology (85%) of the beta subunit with one of the polypeptides of a chicken adhesion receptor complex referred to as integrin complex strongly suggests that the latter polypeptide is the chicken homologue of the fibronectin receptor beta subunit. These receptor subunit homologies define a superfamily of adhesion receptors. The availability of the entire protein sequence for the fibronectin receptor will facilitate studies on the functions of these receptors.     

Subunit interactions involved in the assembly of pyridine nucleotide transhydrogenase in the membranes of Escherichia coli.

The pyridine nucleotide transhydrogenase (PNT) of Escherichia coli consists of two different subunits (alpha and beta) and assembles as a tetramer (alpha 2 beta 2) in the inner membrane. The pnt genes from E. coli have been cloned on a multicopy plasmid resulting in high level expression of the enzyme activity. We have studied the influence of the different segments of the polypeptide chains of the alpha and beta subunits on the assembly and function of the enzyme by constructing a series of deletion mutants for both of the subunits. Our results show that the assembly of the beta subunit is contingent upon the insertion of the alpha subunit into the membrane, while the alpha subunit can assemble independently of the beta subunit. All deletions constructed for the cytosolic portion of the alpha subunit gave no incorporation of the alpha subunit and, as a consequence, of the beta subunit, also. Of the four membrane-spanning regions of the alpha subunit, the last two were indispensable, while the deletion of the first two still allowed the association of alpha as well as of the beta subunit with the membrane. However, the enzyme was not functional. The two subunits were also loosely associated as mild detergent treatment released them from the membrane in contrast with the wild-type enzyme. Deletions within the beta subunit had little effect on the assembly of the alpha subunit, although less was incorporated. All deletions involving the cytosolic portion of the beta subunit resulted in loss of incorporation into the membrane. Of the eight membrane-spanning regions of the beta subunit, the deletion of regions 2-3, 2-4, 2-6, and 2-7 yielded significant association of both the subunits with the membrane. However, none of these mutants assembled a functional enzyme, and again the two subunits were loosely associated with the membrane. Based on the stringent requirement of the cytosolic portions of alpha and beta subunits for assembly, a model is proposed that suggests interactions between these two regions must occur prior to assembly.     

The beta subunit dissociates readily from the Escherichia coli DNA polymerase III holoenzyme

Purified DNA polymerase III holoenzyme (holoenzyme) was separated by glycerol gradient sedimentation into the beta subunit and the subassembly that lacks it (pol III). In the presence of ATP, beta subunit dimer dissociated from holoenzyme with a KD of 1 nM; in the absence of ATP, the KD was greater than 5 nM. The beta subunit was known to remain tightly associated in the holoenzyme upon formation of an initiation complex with a primed template and during the course of replication. With separation from the template, holoenzyme dissociated into beta and pol III. Cycling to a new template depended on the reformation of holoenzyme. Holoenzyme was in equilibrium with pol III and the beta subunit in crude enzyme fractions as well as in pure preparations.     

Separation, amino-terminal sequence and cell-free synthesis of the smallest subunit of sweet potato cytochrome c oxidase

The smallest subunit (V) of sweet potato cytochrome c oxidase was separated into three polypeptides, Va, Vb and Vc with different molecular masses (7.4 kDa, 6.8 kDa and 6.2 kDa respectively) by highly resolving sodium dodecylsulfate polyacrylamide gel electrophoresis. Antibody against subunit V reacted specifically with the polypeptide Vc. When polyadenylated mRNA from sweet potato root tissue was translated in a wheat germ cell-free system, the smallest subunit (Vc) of the polypeptides was synthesized to the same size as the mature form, which suggests that the mature subunit retains the signal for import into mitochondria. Within the N-terminal first 25 amino acids there is a stretch of 16 non-polar residues, periodically linked by basic residues, which might form an amphiphilic helix as the targeting signal.     

A conserved lysine residue in the crenarchaea-specific loop is important for the crenarchaeal splicing endonuclease activity

In Archaea, splicing endonuclease (EndA) recognizes and cleaves precursor RNAs to remove introns. Currently, EndAs are classified into three families according to their subunit structures: homotetramer, homodimer, and heterotetramer. The crenarchaeal heterotetrameric EndAs can be further classified into two subfamilies based on the size of the structural subunit. Subfamily A possesses a structural subunit similar in size to the catalytic subunit, whereas subfamily B possesses a structural subunit significantly smaller than the catalytic subunit. Previously, we solved the crystal structure of an EndA from Pyrobaculum aerophilum. The endonuclease was classified into subfamily B, and the structure revealed that the enzyme lacks an N-terminal subdomain in the structural subunit. However, no structural information is available for crenarchaeal heterotetrameric EndAs that are predicted to belong to subfamily A. Here, we report the crystal structure of the EndA from Aeropyrum pernix, which is predicted to belong to subfamily A. The enzyme possesses the N-terminal subdomain in the structural subunit, revealing that the two subfamilies of heterotetrameric EndAs are structurally distinct. EndA from A. pernix also possesses an extra loop region that is characteristic of crenarchaeal EndAs. Our mutational study revealed that the conserved lysine residue in the loop is important for endonuclease activity. Furthermore, the sequence characteristics of the loops and the positions towards the substrate RNA according to a docking model prompted us to propose that crenarchaea-specific loops and an extra amino acid sequence at the catalytic loop of nanoarchaeal EndA are derived by independent convergent evolution and function for recognizing noncanonical bulge-helix-bulge motif RNAs as substrates.     

Conserved amphipathic helices near the N-terminus and C-terminus of the alpha subunit of cranin (dystroglycan)

Cranin (dystroglycan) is a ubiquitously expressed extracellular matrix receptor, synthesized as a single precursor, which is cleaved into an extracellular subunit (alpha) and a transmembrane subunit (beta). The primary sequence of cranin (dystroglycan) is known from cDNA cloning, and the protein has been strongly implicated in morphogenesis, cell adhesion and human disease. Nevertheless, the domain structure of the alpha subunit has not been well studied; although the protein binds to matrix proteins, to the beta subunit, to cell surfaces, and possibly to other membrane proteins such as sarcoglycans, the domains responsible for mediating these interactions remain unknown. Here I report computer analyses that identify two distinctive amphipathic alpha-helical regions near the N-terminus and C-terminus of the alpha subunit, which are conserved in all species for which sequence information is currently available. This finding should stimulate and guide experimental studies designed to understand how the alpha subunit is associated with the cell surface and with its various ligands.     

Conserved Amphipathic Helices Near the N-Terminus and C-Terminus of the Alpha Subunit of Cranin (Dystroglycan)

Cranin (dystroglycan) is a ubiquitously expressed extracellular matrix receptor, synthesized as a single precursor, which is cleaved into an extracellular subunit (alpha) and a transmembrane subunit (beta). The primary sequence of cranin (dystroglycan) is known from cDNA cloning, and the protein has been strongly implicated in morphogenesis, cell adhesion and human disease. Nevertheless, the domain structure of the alpha subunit has not been well studied; although the protein binds to matrix proteins, to the beta subunit. to cell surfaces, and possibly to other membrane proteins such as sarcoglycans, the domains responsible for mediating these interactions remain unknown. Here I report computer analyses that identify two distinctive amphipathic alpha-helical regions near the N-terminus and C-terminus of the alpha subunit, which are conserved in all species for which sequence information is currently available. This finding should stimulate and guide experimental studies designed to understand how the alpha subunit is associated with the cell surface and with its various ligands.     

Chloroplast transport of a ribulose bisphosphate carboxylase small subunit-5-enolpyruvyl 3-phosphoshikimate synthase chimeric protein requires part of the mature small subunit in addition to the transit peptide

Ribulose bisphosphate carboxylase small subunit protein is synthesized in the cytoplasm as a precursor and transported into the chloroplast where the amino-terminal portion, the transit peptide, is removed proteolytically. To obtain chloroplast delivery of the 43-kDa 5-enolpyruvyl 3-phosphoshikimate (EPSP) synthase of Salmonella typhimurium, we constructed fusion proteins between the bacterial EPSP synthase and the ribulose bisphosphate carboxylase small subunit. A fusion protein consisting of the transit peptide fused to the EPSP synthase was not transported in vitro or in vivo into chloroplasts. A second fusion protein consisting of the transit peptide and 24 amino acids of the mature small subunit fused to the EPSP synthase was transported both in vitro and in vivo into chloroplasts. It was processed into two polypeptides of 46 and 47 kDa, respectively. This heterogeneity in processing was not caused by the presence of the aroA start codon, since its removal resulted in the same pattern. Substituting 24 different amino acids for the 24 amino acids of the mature small subunit resulted in a fusion protein that was not transported into the chloroplast. It was concluded that a portion of the mature small subunit was needed for efficient chloroplast delivery.     

Characterization of Shiga-like toxin I B subunit purified from overproducing clones of the SLT-I B cistron.

The cistron encoding the B subunit of Escherichia coli Shiga-like toxin I (SLT-I) was cloned under control of the tac promoter in the expression vector pKK223-3 and the SLT-I B subunit was expressed constitutively in a wild-type background and inducibly in a lacIq background. The B subunit was located in the periplasmic space, and less than 10% was found in the culture medium after 24 h incubation. Polymyxin B extracts contained as much as 160 micrograms of B subunit/ml of culture. B subunit was purified to homogeneity by ion-exchange chromatography followed by chromatofocusing. Cross-linking analysis of purified native B subunit showed that it exists as a pentamer. In gels containing 0.1% SDS the native protein dissociated into monomers. B subunit was found to have the same glycolipid-receptor-specificity as SLT-I holotoxin. Competitive binding studies showed that B subunit and holotoxin had the same affinity for the globotriosylceramide receptor. We conclude that this recombinant plasmid is a convenient source of large amounts of purified SLT-I B subunit, which could be used for biophysical and structural studies or as a natural toxoid.     

Biogenesis of the cytochrome bc1 complex of yeast mitochondria. A precursor form of the cytoplasmically made subunit V.

The cytoplasmically made subunit V of the yeast mitochondrial cytochrome bc1 complex is synthesized as a larger polypeptide in vitro. This was shown by programming a reticulocyte lysate with yeast RNA and immunoprecipitating the labeled translation products with a subunit V-specific antiserum. The larger form of subunit V could also be detected in pulse-labeled spheroplasts; upon a subsequent chase, most of it disappeared. A proteolytic fingerprint of the larger form was closely similar to that of the mature subunit. These data suggest that the cytoplasmically made subunit V is translated as a larger precursor which is cleaved to the mature subunit either during or after its entry into the mitochondria.     

Formation of the small subunit in the absence of the large subunit of ribulose 1,5-bisphosphate carboxylase in 70 S ribosome-deficient rye leaves.

Immunological tests with monospecific antisera to ribulosebisphosphate carboxylase (EC 4.1.1.39) and to its large and small subunits indicated the presence of a protein with antigenic properties of the small subunit in the absence of the large subunit in the leaves of young rye plants (Secale cereale L.) with a high-temperature-induced (32 °C) deficiency of 70 S plastid ribosomes. The small subunit-like protein was isolated from crude extracts of plastid ribosome-deficient 32 °C-grown leaf tissue by the use of columns with immobilized antibody. The main polypeptide retained by the immobilized antibodies had the same mobility after electrophoresis on sodium dodecyl sulfate-polyacrylamide gels as the small subunit of ribulosebisphosphate carboxylase and was also immunologically identical to the small subunit. The small subunit-like protein was present in the supernatant as well as in the membrane fraction of isolated 70 S ribosome-deficient plastids. At very young stages of normal leaves grown at a permissive temperature (22 °C) an excess of small subunit was observed that was also not integrated into the complete ribulosebisphosphate carboxylase molecule. From the results, we conclude that the synthesis of the small subunit occurs on cytoplasmic ribosomes and is not strictly coordinated with the translation of the large subunit in the chloroplast. During early leaf development, the formation of the large subunit seems to be the ratelimiting step in the synthesis of ribulosebisphosphate carboxylase.     

The Na(+)-translocating F(1)F(0) ATP synthase of Propionigenium modestum: mechanochemical insights into the F(0) motor that drives ATP synthesis

The ATP synthase of Propionigenium modestum encloses a rotary motor involved in the production of ATP from ADP and inorganic phosphate utilizing the free energy of an electrochemical Na(+) ion gradient. This enzyme clearly belongs to the family of F(1)F(0) ATP synthases and uses exclusively Na(+) ions as the physiological coupling ion. The motor domain, F(0), comprises subunit a and the b subunit dimer which are part of the stator and the subunit c oligomer acting as part of the rotor. During ATP synthesis, Na(+) translocation through F(0) proceeds from the periplasm via the stator channel (subunit a) onto a Na(+) binding site of the rotor (subunit c). Upon rotation of the subunit c oligomer versus subunit a, the occupied rotor site leaves the interface with the stator and the Na(+) ion can freely dissociate into the cytoplasm. Recent experiments demonstrate that the membrane potential is crucial for ATP synthesis under physiological conditions. These findings support the view that voltage generates torque in F(0), which drives the rotation of the gamma subunit thus liberating tightly bound ATP from the catalytic sites in F(1). We suggest a mechanochemical model for the transduction of transmembrane Na(+)-motive force into rotary torque by the F(0) motor that can account quantitatively for the experimental data.