Genes for respiratory chain proteins and ribosomal RNAs are present on a 16-kilobase-pair DNA species from Chlamydomonas reinhardtii mitochondria.

We have used heterologous hybridization and DNA sequence analysis to determine whether the 16-kilobase-pair (kbp) DNA from Chlamydomonas reinhardtii mitochondria is the functional equivalent of mtDNA in other eukaryotes. Restriction fragments corresponding to a continuous internal stretch spanning 75% of the 16-kbp DNA have been cloned and mapped, and regions hybridizing with probes specific for the cytochrome oxidase subunit I [CytOx I (acronym COI)] and apocytochrome b (Cyt b) genes of yeast and the mitochondrial 26S and 18S rRNA genes of wheat have been identified. Sequence analysis has verified the presence of CytOx I and the large and small subunit rRNA genes in the C. reinhardtii 16-kbp DNA. In the region of the 16-kbp DNA corresponding to exon 4 in the yeast CytOx I gene, the derived amino acid sequence is 61% and 63% identical with the CytOx I amino acid sequences of yeast and human mitochondria, respectively. Notably, tryptophan is specified by TGG rather than by TGA in this section of the C. reinhardtii CytOx I gene. A probe from the CytOx I region of the 16-kbp DNA hybridizes only with this 16-kbp DNA in Southern blots of total cellular DNA from C. reinhardtii but with a larger DNA species in the total cellular DNA of C. moewusii and C. eugametos--two species that lack a 16-kbp DNA. These observations provide evidence that C. reinhardtii 16-kbp DNA comprises at least part of the mitochondrial genome of this organism and that a homologous DNA exists in other species of Chlamydomonas.     

"Retroposon" insertion into the cellular oncogene c-myc in canine transmissible venereal tumor.

We examined by Southern blotting the state of the cellular oncogene c-myc in the dog transmissible venereal tumor. The tumor DNA contains a 16.8-kilobase pair (kbp) rearranged c-myc fragment in addition to the normal 15-kbp and 7.5-kbp fragments. We compared the structure of the cloned rearranged c-myc (re-myc) with that of a cloned normal c-myc and found that the rearrangement was due to the insertion of a 1.8-kbp DNA upstream to the first exon of c-myc. The inserted DNA is flanked by 10-base-pair direct repeats and contains a dA-rich tail, suggesting its origin from mRNA. Partial sequence of the inserted element showed 62% homology with the primate interdispersed Kpn I repetitive element. These results provide an example for the behavior of repetitive DNA sequences like the Kpn I family, as movable elements that can transpose nearby to oncogenes or other structural genes and perhaps affect their activity.     

Molecular cloning of integrated simian sarcoma virus: genome organization of infectious DNA clones

The integrated form of simian sarcoma virus (SSV) was molecularly cloned in the Charon 16A strain of bacteriophage lambda. In transfection analysis, the recombinant viral DNAs demonstrated the ability to transform cells in tissue culture at high efficiency. Such transformants possessed typical SSV morphology, expressed simian sarcoma associated virus (SSAV) gag gene products in the absence of virus release, and released SSV after superinfection with a type C helper virus. A physical map of the 5.8-kilobase-pair (kbp) recombinant viral DNA clone, deduced from restriction endonuclease analysis, revealed a 5.1-kbp SSV genome containing 0.55-kbp-long terminal repeats flanked by 0.45 and 0.25 kbp of contiguous host cell sequences. By R-loop analysis, the viral DNA molecule contained two regions of homology to SSAV, separated by a 1.0-kbp nonhomologous region. This SSV-specific sequence was shown to be uniquely represented within the normal cellular DNA of diverse mammalian species, including human. Our results demonstrate that this primate transforming retrovirus arose in nature by recombination of a type C helper virus and a host cellular gene.     

Endonuclease recognition sites mapped on Zea mays chloroplast DNA

The closed-circular DNA molecules of 85 × 10⁶ daltons from Zea mays chloroplasts were isolated, digested with the restriction endonucleases Sal I, Bam I, and EcoRI, and the resulting fragments sized by agarose gel electrophoresis. A map of maize chloroplast DNA showing the relative location of all the Sal I recognition sequences and many of the Bam I and EcoRI recognition sites was determined. A DNA sequence representing approximately 15% of the Zea mays chloroplast genome is repeated. The two copies of this sequence are in an inverted orientation with respect to one another and are separated by a nonhomologous sequence representing approximately 10% of the genome length. The inverted repeats contain the genes for chloroplast ribosomal RNAs.     

Molecular cloning and chromosomal mapping of a human locus related to the transforming gene of Moloney murine sarcoma virus.

Human DNA was analyzed for the presence of sequences homologous to the transforming gene (v-mos) of Moloney murine sarcoma virus. A single 2.5-kilobase pair (kbp) EcoRI-generated fragment of human DNA was identified by using cloned v-mos as probe. This DNA was molecularly cloned in a bacteriophage vector. By heteroduplex and restriction enzyme analyses, this human DNA fragment, designated c-mos (human), contained a 0.65-kbp region of continuous homology with v-mos and was present as a single copy in human DNA. By testing for the presence of c-mos (human) in somatic cell hybrids possessing various numbers of human chromosomes, as well as in subclones of such hybrids, it was possible to assign c-mos (human) to human chromosome 8.     

A homolog of Escherichia coli RecA protein in plastids of higher plants.

Studies of chloroplast DNA variations, and several direct experimental observations, indicate the existence of recombination ability in algal and higher plant plastids. However, no studies have been done of the biochemical pathways involved. Using a part of a cyanobacterial recA gene as a probe in Southern blots, we have found homologous sequences in total DNA from Pisum sativum and Arabidopsis thaliana and in a cDNA library from Arabidopsis. A cDNA was cloned and sequenced, and its predicted amino acid sequence is 60.7% identical to that of the cyanobacterial RecA protein. This finding is consistent with our other results showing both DNA strand transfer activity and the existence of a protein of the predicted molecular mass crossreactive with antibodies to Escherichia coli RecA in the stroma of pea chloroplasts.     

Cloning and localization of the lepidopteran protoxin gene of Bacillus thuringiensis subsp. kurstaki.

Bacillus thuringiensis subsp. kurstaki produces a proteinaceous crystalline inclusion that is toxic for lepidopteran larvae. There are several size classes of plasmids in this organism and the presence of one or more has been correlated with production of this protein, defined as a protoxin. DNA fragments of B. thuringiensis subsp. kurstaki, obtained by EcoRI digestion, were cloned into the vector Charon 4A. Recombinant phage were screened immunologically for the production of protoxin. Cells infected with one phage, C4K6c, produced antigen that was the same size as the protoxin and was toxic to Manduca sexta larvae. A 4.6-kilobase-pair (kbp) EcoRI fragment from C4K6c was subcloned into pBR328 and in both orientations in pHV33. Both Escherichia coli and Bacillus subtilis containing these recombinant plasmids produced antigen that crossreacted with antibody directed against the protoxin. The various sized plasmids of B. thuringiensis were purified and only an EcoRI fragment from the 45-kbp plasmid hybridized to phage C4K6c. One of the pHV33 subclones, pSM36, hybridized to the same size EcoRI/HindIII restriction fragments from plasmid or chromosomal DNA. The cloned EcoRI fragment contained a 0.9-kbp Pvu II fragment that was also present in chromosomal but not in plasmid digests. The original clone was therefore of chromosomal origin, although very similar or identical protoxin genes were present in both the 45-kbp plasmid and the chromosome. Several acrystalliferous nontoxic mutants have been isolated that lacked the 45-kbp plasmid and in some cases all plasmids. All of the mutants contained the chromosomal gene but did not produce protoxin antigen.     

Extensive sequence homology in the DNA coding for elongation factor Tu from Escherichia coli and the Chlamydomonas reinhardtii chloroplast.

Considerable DNA sequence homology can be detected between the Escherichia coli genes coding for translational components and Chlamydomonas reinhardtii chloroplast DNA. Labeled chloroplast DNA was found to hybridize to restriction fragments of the transducing phage lambda fus3 that code for elongation factor Tu. The chloroplast probe also reacts with fragments coding for ribosomal proteins carried by this phage. The region homologous to the elongation factor genes was located on the physical map of the chloroplast genome by probing restriction fragments of chloroplast DNA with cloned fragments, labeled in vitro, carrying the E. coli elongation factor Tu genes.     

Structure and function of a chloroplast DNA replication origin of Chlamydomonas reinhardtii

Chloroplast DNA replication in Chlamydomonas reinhardtii is initiated by the formation of a displacement loop (D-loop) at a specific site. One D-loop site with its flanking sequence was cloned in recombinant plasmids SC3-1 and R-13. The sequence of the chloroplast DNA insert in SC3-1, which includes the 0.42-kilobase (kb) D-loop region, as well as 0.2 kb to the 5′ end and 0.43 kb to the 3′ end of the D-loop region, was determined. The sequence is A+T-rich and contains four large stem-loop stuctures. An open reading frame potentially coding for a polypeptide of 136 amino acids was detected in the D-loop region. One stem-loop structure and two back-to-back prokaryotic-type promoters were mapped within the open reading frame. The 5.5-kb EcoRI fragment cloned in R-13 contains the 1.05-kb SC3-1 insert and its flanking regions. A yeast autonomously replicating (ARS) sequence and an ARC sequence, which promotes autonomous replication in Chlamydomonas, have been mapped within the flanking regions [Vallet, J.-M. & Rochaix, J.-D. (1985) Curr. Genet. 9, 321-324]. Both R-13 and SC3-1 were active as templates in a crude algal preparation that supports DNA synthesis. In this in vitro system, chloroplast DNA synthesis initiated near the D-loop site.     

Photodestruction of chloroplast ultrastructure by red light: location of chlorophyll

A lethal dose (1 Mrad) of gamma rays was given to wheat leaf tissue to restrict migration of the energy of red light photoexcitation to the photosynthetic pigment system. This dose of gamma radiation had no apparent effect on chloroplast ultrastructure in tissue that received no illumination. Subsequent illumination with red light, used to induce chlorophyll-sensitized photodestruction of ultrastructure, permitted inferences about the location of chlorophyll within the chloroplast. The red light produced extensive disruption in chloroplasts but not in any other cellular organelles. The sequence of events in this photodestruction was different from that which occurs when chloroplasts are destroyed by methods that do not involve illumination. The red light caused peculiar abnormalities only in the internal lamellar system of the chloroplast and not in the envelope or any other regions. These findings support other studies which suggest that chlorophyll is located exclusively in grana and stroma lamellae.     

Extensive and widespread homologies between mitochondrial DNA and chloroplast DNA in plants

We used hybridization techniques to demonstrate that numerous sequence homologies exist between cloned mung bean and spinach chloroplast DNA (ctDNA) restriction fragments and mtDNAs from corn, mung bean, spinach, and pea. The strongest cross-homologies are between clones derived from the ctDNA inverted repeat and mtDNA from corn and pea, although all the ctDNA clones tested hybridized to at least one mtDNA restriction fragment. Known chloroplast genes showing strong mtDNA homologies include those for the large subunit of ribulosebisphosphate carboxylase, which hybridizes to corn mtDNA, and the β subunit of the chloroplast ATPase, which hybridizes to mung bean mtDNA. Certain of these homologies were confirmed by using cloned spinach mtDNA restriction fragments as probes in reciprocal hybridizations to ctDNA. Several of these ctDNA-homologous mtDNA sequences were shown to be much more closely related to ctDNA from the same species than to that of a distantly related species. We interpret these differential homologies as evidence for relatively recent DNA sequence transfer events, suggesting that transpostion between the two genomes is an ongoing evolutionary process.