Faculty Bibliography

Mutations at the URA3 locus of Saccharomyces cerevisiae can be obtained by a positive selection. Wild-type strains of yeast (or ura3 mutant strains containing a plasmid-borne URA3+ gene) are unable to grow on medium containing the pyrimidine analog 5-fluoro-orotic acid, whereas ura3- mutants grow normally. This selection, based on the loss of orotidine-5'-phosphate decarboxylase activity seems applicable to a variety of eucaryotic and procaryotic cells.

The histidine-rich protein (HRP) of the avian malaria parasite Plasmodium lophurae contains 70% histidine. It is found in dense cytoplasmic granules and during the erythrocytic cycle it accumulates to represent 10% of the dry weight of the parasite. In the present work the HRP mRNA was studied by in vitro translation and by the use of a polyhistidine oligonucleotide probe. The HRP mRNA contains 2,000-2,100 nucleotides encoding a protein with an apparent molecular weight of 50,000. In addition a HRP of molecular weight 35,000-40,000 is also produced in vitro, probably as a result of proteolytic cleavage of the molecular weight 50,000 polypeptide which corresponds to in vivo labeled and purified HRP. The HRP represents a much larger proportion of the in vitro products synthesized in the homologous cell-free system compared to the rabbit reticulocyte system, and it reflects more closely the pattern of protein synthesis seen in vivo. In addition, HRP mRNA is more abundant in polysomes isolated from young parasites than in polysomes from mature schizonts. These results indicate that the HRP accumulates as a result of amplified translation of its mRNA at certain stages of its erythrocytic cycle.

A Staphylococcus aureus plasmid derivative, pFB9, coding for erythromycin and chloramphenicol resistance was cloned into the filamentous Escherichia coli phage f1. Recombinant phage-plasmid hybrids, designated plasmids, were isolated from E. coli and purified by transformation into Streptococcus pneumoniae. Single-stranded DNA was prepared from E. coli cells infected with two different plasmids, fBB101 and fBB103. Introduction of fully or partially single-stranded DNA into Streptococcus pneumoniae was studied, using a recipient strain containing an inducible resident plasmid. Such a strain could rescue the donor DNA marker. Under these marker rescue conditions, single-stranded fBB101 DNA gave a 1% transformation frequency, whereas the double-stranded form gave about a 31% frequency. Transformation of single-stranded fBB101 DNA was inhibited by competing double-stranded DNA and vice versa, indicating that single-stranded DNA interacts with the pneumococcus via the same binding site as used by double-stranded DNA. Heteroduplexed DNA containing the marker within a 70- or 800-base single-stranded region showed only slightly greater transforming activity than pure single-stranded DNA. In the absence of marker rescue, both strands of such imperfectly heteroduplexed DNA demonstrated transforming activity. Pure single-stranded DNA demonstrated low but significant transforming activity into a plasmid-free recipient pneumococcus.

Gene III protein of bacteriophage f1 is inserted into the host cell membrane where it is assembled into phage particles. A truncated form of gene III protein, encoded by a recombinant plasmid and lacking the carboxyl terminus, does not remain in the membrane but instead appears to slip through it. Fusion of a hydrophobic "membrane anchor" from another membrane protein, the gene VIII protein, to the truncated gene III protein (by manipulation of the recombinant plasmid) restores membrane anchoring. A model for the relationship of gene III protein with the Escherichia coli membrane is discussed.

Derivatives of filamentous phage, f1, fd, and M13, useful as cloning vectors are listed, and procedures for their use are reviewed. Methods for growing phage, preparing single- and double-stranded DNA, and cloning are given in the "cook-book" form. These procedures minimize the practical problem often associated with filamentous-phage cloning, i.e., deletion of inserts.

Plasmid pSA5700 from Staphylococcus aureus coding for erythromycin (EmR) and chloramphenicol (CmR) resistance was transformed into Streptococcus pneumoniae. High-copy-number and EmR constitutive mutants of this plasmid were isolated. Transformation frequencies in S. pneumoniae as high as 70% were obtained with a constitutive plasmid as donor DNA, into a recipient cell containing a resident, inducible, high-copy-number plasmid. With the aid of these high frequencies, the site of constitutive mutations could be mapped via a simple marker rescue technique that uses purified restriction endonuclease-generated fragments. One of the EmR constitutive mutants, pFB9, a plasmid originating from a Gram-positive host, was shown to replicate and express EmR and CmR in a Gram-negative organism, Escherichia coli. Four derivatives of pFB9 containing large (0.6-0.9 megadalton) insertion sequences that arose spontaneously in E. coli demonstrated unusual transforming activity, as well as enhanced EmR, in E. coli. The inserted elements mapped to the region in front of the EmR gene. Three of these inserted elements had the size and restriction patterns of insertion sequence IS1, IS2, and IS5. Plasmid pFB9 and derivatives are useful for isolation of new insertion sequences and for comparison of gene expression and illegitimate recombination between Gram-positive and Gram-negative species.

Plasmids which encode bacteriophage f1 coat protein genes VIII and III are responsible for a number of unusual properties suggesting that they have a drastic effect on the bacterial outer membrane. Analysis of several such recombinant plasmids and selection of mutant plasmids unable to cause this effect established that the properties were caused by gene III protein or its amino-terminal fragment.

The assembly of filamentous bacteriophages has been studied in cells infected by wild-type and mutant phage; host mutants defective in bacteriophage assembly have also been isolated. Phage assembly takes place at the membrane, and requires insertion of the viral major coat protein. We present data on the physiology of this process and on the effects of amino acid sequence variations near to the coat protein amino terminus on membrane insertion, processing, and phage assembly.