Multiple-copy genes: production and modification of monomeric peptides from large multimeric fusion proteins.

A vector system has been designed for obtaining high yields of polypeptides synthesized in Escherichia coli. Multiple copies of a synthetic gene encoding the neuropeptide substance P (SP) (Arg-Pro-Lys-Pro-Gln-Gln-Phe-Phe-Gly-Leu-Met-NH2) have been linked and fused to the lacZ gene. Each copy of the SP gene was flanked by codons for methionine to create sites for cleavage by cyanogen bromide (CNBr). The isolated multimeric SP fusion protein was converted to monomers of SP analog, each containing a carboxyl-terminal homoserine lactone (Hse-lactone) residue (Arg-Pro-Lys-Pro-Gln-Gln-Phe-Phe-Gly-Leu-Hse-lactone), upon treatment with CNBr in formic acid. The Hse-lactone moiety was subjected to chemical modifications to produce an SP Hse amide. This method permits synthesis of peptide amide analogs and other peptide derivatives by combining recombinant DNA techniques and chemical methods.

Nucleotide sequence of cloned unintegrated avian sarcoma virus DNA: viral DNA contains direct and inverted repeats similar to those in transposable elements.

We have determined the nucleotide sequence of portions of two circular avian sarcoma virus (ASV) DNA molecules cloned in a prokaryotic host--vector system. The region whose sequence was determined represents the circle junction site--i.e., the site at which the ends of the unintegrated linear DNA are fused to form circular DNA. The sequence from one cloned molecule, SRA-2, shows that the circle junction site is the center of a 330-base-pair (bp) tandem direct repeat, presumably representing the fusion of the long terminal repeat (LTR) units known to be present at the ends of the linear DNA. The circle junction site is also the center of a 15-bp imperfect inverted repeat, which thus appears at the boundaries of the LTR. The structure of ASV DNA--unique coding region flanked by a direct repeat that is, in turn, terminated with a short inverted repeat--is very similar to the structure of certain transposable elements. Several features of the sequence imply that circularization to form the SRA-2 molecule occurred without loss of information from the linear DNA precursor. Circularization of another cloned viral DNA molecule, SRA-1, probably occurred by a different mechanism. The circle junction site of the SRA-1 molecule has a 63-bp deletion, which may have arisen by a mechanism that is analogous to the integration of viral DNA into the host genome. Flanking one side of the tandem direct repeat is the binding site for tRNATrp, the previously described primer for synthesis of the first strand of viral DNA. The other side of the direct repeat is flanked by a polypurine tract, A-G-G-G-A-G-G-G-G-G-A, which may represent the position of the primer for synthesis of the second strand of viral DNA. An A+T-rich region, upstream from the RNA capping site, and the sequence A-A-T-A-A-A are present within the direct repeat sequence. These sequences may serve as a promoter site and poly(A) addition signal, respectively, as proposed for other eukaryotic transcription units.

Molecular cloning and characterization of avian sarcoma virus circular DNA molecules.

Supercoiled DNA molecules were used for the molecular cloning of full-length avian sarcoma virus (ASV) DNA. Viral DNA produced by the Schmidt-Ruppin A (SR-A) strain of ASV was isolated from acutely infected transformed quail cells. Supercoiled DNA was separated from linear and open circular DNA by acid phenol extraction, opened into a full-length linear form by cleavage with the restriction endonuclease SacI, and cloned into lambda gtWES x lambda B. Four different cloned viral DNA molecules were isolated: SRA-1 contains two copies of the 330-base pair terminal redundancy normally found at each end of the linear DNA molecules, but harbors a 63-base pair deletion that spans the site at which the two copies of the terminal redundancy are joined in circular DNA molecules; SRA-2 contains two complete copies of the terminal redundancy; SRA-3 probably contains only one copy of the terminal redundancy but in all other respects appears to be similar to SRA-2; SRA-4 contains a 2,500-base pair deletion that removes all of the src gene (the gene responsible for transformation by ASVs) plus additional nucleotides adjacent to the src gene whose precise locations have not been determined. Transfection of chicken embryo fibroblasts by either SRA-1 or SRA-2 resulted both in the appearance of transformed cells and in the production of infectious virus. These results demonstrate that the cloned DNA molecules are functionally identical to viral DNA produced in vivo; therefore, molecular cloning did not cause any major alterations of the DNA. The infectivity of SRA-1 DNA indicates that the 63 base pairs missing from that molecule are not required for the initiation of viral RNA synthesis, even though the deletion is located in a copy of the terminal redundancy thought to carry a promoter for RNA synthesis. This suggests that the deletion does not remove any sequences required for the initiation of transcription.

Inactivation of E. coli RNA polymerase by polyriboinosinic acid: heterogeneity of RS complexes.

Polyriboinosinic acid (poly I) inhibits initiation of transcription by binary complexes formed between Adenovirus 2 DNA and E. coli RNA polymerase holoenzyme. In the presence of poly I, just as in the presence of rifampicin, initiation of transcription exhibits a sigmoidal dependence on the temperature at which the binary complexes are formed. This indicates that I (closed) complexes between Ad 2 DNA and RNA polymerase are rapidly inactivated by poly I, but that RS (open) complexes are relatively resistant. However, even among the RS complexes, at least two classes can be distinguished on the basis of the degree to which they are resistant to poly I: RS-1 complexes are somewhat sensitive to poly I (half-time of inactivation approximately 10 min) while RS-2 complexes are almost completely resistant to the inhibitor (half-time of inactivation approximately 10 h). For both types of RS complex, the degree of sensitivity to poly I is ionic strength-dependent.