A protein interaction map of Drosophila melanogaster.

Drosophila melanogaster is a proven model system for many aspects of human biology. Here we present a two-hybrid-based protein-interaction map of the fly proteome. A total of 10,623 predicted transcripts were isolated and screened against standard and normalized complementary DNA libraries to produce a draft map of 7048 proteins and 20,405 interactions. A computational method of rating two-hybrid interaction confidence was developed to refine this draft map to a higher confidence map of 4679 proteins and 4780 interactions. Statistical modeling of the network showed two levels of organization: a short-range organization, presumably corresponding to multiprotein complexes, and a more global organization, presumably corresponding to intercomplex connections. The network recapitulated known pathways, extended pathways, and uncovered previously unknown pathway components. This map serves as a starting point for a systems biology modeling of multicellular organisms, including humans.

Multivalent binding of nonnative substrate proteins by the chaperonin GroEL.

The chaperonin GroEL binds nonnative substrate protein in the central cavity of an open ring through exposed hydrophobic residues at the inside aspect of the apical domains and then mediates productive folding upon binding ATP and the cochaperonin GroES. Whether nonnative proteins bind to more than one of the seven apical domains of a GroEL ring is unknown. We have addressed this using rings with various combinations of wild-type and binding-defective mutant apical domains, enabled by their production as single polypeptides. A wild-type extent of binary complex formation with two stringent substrate proteins, malate dehydrogenase or Rubisco, required a minimum of three consecutive binding-proficient apical domains. Rhodanese, a less-stringent substrate, required only two wild-type domains and was insensitive to their arrangement. As a physical correlate, multivalent binding of Rubisco was directly observed in an oxidative cross-linking experiment.

GroEL-GroES cycling: ATP and nonnative polypeptide direct alternation of folding-active rings.

The double-ring chaperonin GroEL mediates protein folding in the central cavity of a ring bound by ATP and GroES, but it is unclear how GroEL cycles from one folding-active complex to the next. We observe that hydrolysis of ATP within the cis ring must occur before either nonnative polypeptide or GroES can bind to the trans ring, and this is associated with reorientation of the trans ring apical domains. Subsequently, formation of a new cis-ternary complex proceeds on the open trans ring with polypeptide binding first, which stimulates the ATP-dependent dissociation of the cis complex (by 20- to 50-fold), followed by GroES binding. These results indicate that, in the presence of nonnative protein, GroEL alternates its rings as folding-active cis complexes, expending only one round of seven ATPs per folding cycle.

Residues in chaperonin GroEL required for polypeptide binding and release.

Chaperonins are ring-shaped protein complexes that are essential in the cell, mediating ATP-dependent polypeptide folding in a variety of compartments. Recent studies suggest that they function through multiple rounds of binding and release of non-native proteins: with each round of ATP-driven release into the bulk solution, a substrate protein kinetically partitions between folding to the native state or rebinding to another chaperonin molecule. To gain further insight into the mechanism of polypeptide binding and release by the chaperonin GroEL from Escherichia coli, we have undertaken a mutational analysis that relates the functional properties of GroEL to its crystal structure. Our functional tests identify a putative polypeptide-binding site on the inside surface of the apical domain, facing the central channel, consisting of hydrophobic residues. These same residues are essential for binding of the co-chaperonin GroES, which is required for productive polypeptide release. A highly conserved residue, Asp 87, positioned within a putative nucleotide-binding pocket in the top of the equatorial domain, is essential for ATP hydrolysis and polypeptide release.

Folding in vivo of bacterial cytoplasmic proteins: role of GroEL.

A general role for chaperonin ring structures in mediating folding of newly translated proteins has been suggested. Here we have directly examined the role of the E. coli chaperonin GroEL in the bacterial cytoplasm by production of temperature-sensitive lethal mutations in this essential gene. After shift to nonpermissive temperature, the rate of general translation in the mutant cells was reduced, but, more specifically, a defined group of cytoplasmic proteins--including citrate synthase, ketoglutarate dehydrogenase, and polynucleotide phosphorylase--were translated but failed to reach native form. Similarly, a monomeric test protein, maltose-binding protein, devoid of its signal domain, was translated but failed to fold to its native conformation. We conclude that GroEL indeed is a machine at the distal end of the pathway of transfer of genetic information, assisting a large and specific set of newly translated cytoplasmic proteins to reach their native tertiary structures.

Synthesis of hepadnavirus particles that contain replication-defective duck hepatitis B virus genomes in cultured HuH7 cells.

To evaluate the possibility of producing transducible replication-defective hepadnaviruses, cloned mutant duck hepatitis B virus genomes were tested both for virus antigen production and viral DNA synthesis following transfection into the human hepatoma cell line HuH7. Deletion of a cis-acting 12-nucleotide sequence implicated in viral DNA synthesis, direct repeat 1 (DR1), resulted in the loss of ability to synthesize both mature viral DNA and infectious virus. The delta DR1 mutant, however, produced envelope and core antigens and was shown to provide trans-acting functions required for the assembly of infection-competent particles. Thus, mutants with mutations in viral genes could be rescued as DNA-containing viral particles after cotransfection with delta DR1. The efficiency of rescue was influenced by the site of mutation. A mutant DNA encoding truncated core and envelope proteins not only was poorly rescued but also was able to suppress the production from a wild-type DNA of infectious virus.

Mitochondrial import and processing of mutant human ornithine transcarbamylase precursors in cultured cells.

We have investigated mitochondrial import and processing of the precursor for human ornithine transcarbamylase (OTC; carbamoylphosphate:L-ornithine carbamoyltransferase, EC 2.1.3.3) in HeLa cells stably transformed with cDNA sequences encoding OTC precursors carrying mutations in their leader peptides. The mutant precursors studied included two with amino acid substitutions in the 32-amino-acid leader peptide (glycine for arginine at position 23, designated gly23; glycines for arginines at positions 15, 23, and 26, designated gly15,23,26) and two with deletions (deletion of residues 8 to 22, designated d8-22; deletion of residues 17 to 32, designated N16). Specific immunoprecipitation with anti-OTC antiserum of extracts of L-[35S]methionine-labeled cells expressing these mutations yielded only precursor species; neither mature nor intermediate-size OTC subunits were observed. Fractionation of radiolabeled cells, however, revealed important differences among the various mutants: the gly23 precursor was associated with mitochondria and was not detected in the cytosol; the d8-22 and N16 precursors were found with both the mitochondrial fraction and the cytosol; only the gly15,23,26 precursor was detected exclusively in the cytosol. A large fraction of each of the mitochondrially associated OTC species was in a trypsin-protected compartment. In particular, the gly23 precursor behaved in trypsin protection and mitochondrial fractionation studies in a manner consistent with its translocation into the mitochondrial matrix. On the other hand, the lack of binding of the gly23 protein to a delta-N-phosphonoacetyl-L-ornithine affinity column, which specifically recognizes active OTC enzyme, indicated that, despite its intramitochondrial location, the mutant protein did not assemble into the normal, active trimer. Further, the gly23 mutant precursor was unstable within the mitochondria and was degraded with a t1/2 of less further than 4 h. Thus, we have shown that, in intact HeLa cells, cleavage of the OTC leader peptide is not required for translocation into mitochondria, but is required for assembly into active enzyme.

The ornithine transcarbamylase leader peptide directs mitochondrial import through both its midportion structure and net positive charge.

The cytoplasmically synthesized precursor of the mitochondrial matrix enzyme, ornithine transcarbamylase (OTC), is targeted to mitochondria by its NH2-terminal leader peptide. We previously established through mutational analysis that the midportion of the OTC leader peptide is functionally required. In this article, we report that study of additional OTC precursors, altered in either a site-directed or random manner, reveals that (a) the midportion, but not the NH2-terminal half, is sufficient by itself to direct import, (b) the functional structure in the midportion is unlikely to be an amphiphilic alpha-helix, (c) the four arginines in the leader peptide contribute collectively to import function by conferring net positive charge, and (d) surprisingly, proteolytic processing of the leader peptide does not require the presence of a specific primary structure at the site of cleavage, in order to produce the mature OTC subunit.

Hybridization of restriction fragments derived from calf satellite I DNA.

Two DNA fragments, the 643 base pairs (bp) and 621 bp long, obtained by endoR.Pst nuclease digestion of the 1350 bp basic repetitive unit of the calf satellite I DNA and cloning, do not hybridize with each other. Both of them, however, hybridize with the 970 and 1550 bp fragments, the sequence of which has been found to be homologous with that of the satellite I DNA.

Molecular cloning of the restriction fragments derived from double EcoRI/PstI digestion of the calf satellite I DNA and their restriction analysis.

Calf satellite I DNA digested with EcoRI and PstI gives three fragments 643, 621 and 83 bp long. Two of them, the 643 and 621 bp were cloned using pBR 322 vector and analyzed by means of the MspI and HaeIII restriction enzymes.

The 1360 bp long basic repeat unit of calf satellite I DNA contains GC rich nucleus of about 140 bp.

Fine melting profiles of calf satellite I DNA and its fragments obtained after digestion with endoR.EcoRI and endoR.AluI nucleases were investigated. It is shown that the 1360 bp basic repeat unit of calf satellite I DNA contains an about 140 bp long GC rich nucleus. It is localized on the 600 bp restriction fragment obtained after digestion of 1360 bp fragment with endoR.AluI nuclease. The main part of satellite I DNA melts as loops between such GC rich nuclei which strongly influence the melting properties of this satellite. There exist significant differences between the thermal stabilities of fragments containing many nuclei, one nucleus and those in which such nucleus is absent.