Madeline Wu

Expression of the mitochondrial genome in HeLa cells: XIV. The relative positions of the 4 s RNA genes and of the ribosomal RNA genes in mitochondrial DNA☆☆☆★

Abstract HeLa mitochondrial 4 s RNA has been covalently coupled to the electron opaque label, ferritin, which is visible in the electron microscope. Mixtures of HeLa mitochondrial 12 s ribosomal RNA, 16 s rRNA and/or the 4 s RNA-ferritin conjugate have been hybridized to separated heavy (H) and light (L) strands of HeLa mitochondrial DNA, or to a mixture of H and L strands. The relative positions of the duplex regions corresponding to the 12 s and 16 s rRNA—DNA hybrids and of the ferritin-labeled 4 s RNAs have been mapped in the electron microscope after spreading the DNA strands by the formamide modification of the basic protein film technique. The 12 s and 16 s duplex regions have lengths of 0·-26 ± 0.04 μm and 0.46 ± 0.07 μm, respectively. They are separated by a single-strand region of length 0.047 ± 0.017 μm, corresponding to 160 ± 60 nucleotides. There are nine reproducible binding sites for 4 s RNA on the H strand. One such site lies within the spacer region between the 12 s and 16 s coding sequences, one site is immediately adjacent to the other side of the 12 s sequence and one is adjacent to the other side of the 16 s sequence. The other 4 s sites are rather evenly spaced along the DNA strand of total length 15,600 nucleotides, except that two of them are clustered with a spacing of 120 ± 30 nucleotides between them. There are three 4 s RNA coding sequences on the L strand, separated from one another by 2280 and 3900 nucleotides, respectively.

Sequence arrangement of tRNA genes on a fragment of drosophila melanogaster DNA cloned in E. coli

A plasmid with the vector Col E1 attached to an insert of Drosophila melanogaster DNA carrying four tRNA genes has been cloned in E. coli. Some features of the sequence arrangement and the positions of the tRNA genes have been determined by electron microscopic methods and by restriction endonuclease mapping. tRNA genes were mapped at 1.4, 4.7, 5.9 and 8.6 kb from one of the Drosophila/Col E1 junctions in the Drosophila insert of total length 9.34 kb. There are several secondary structure features consisting of inverted repeat sequences of length about 70-100 nucleotide pairs, some with and some without intervening loops, irregularly distributed on the insert. Cross-hybridization of tRNAs isolated by hybridization to separated restriction fragments indicate that the tRNA genes at 4.7, 5.9 and 8.6 kb are identical and differ from the one at 1.4 kb. Thus the positions of the genes, of the secondary structure features and of the restriction endonuclease sites all indicate that the spacers between the genes are not identical tandem repeats. In situ hybridization with cRNA transcribed from the plasmid showed localization at region 42A of chromosome 2R.

The relative positions of sea urchin histone genes on the chimeric plasmids pSp2 and pSp17 as studied by electron microscopy

The relative positions of the sea urchin histone genes and the spacer regions on the chimeric plasmids pS p2 and pSp17 have been mapped by hybridizing total histonemessenger RNA to single strands of the plasmid DNAs. The lengths and spacing between the several RNA:DNA duplex regions on the single strands of DNA were measured by the gene 32-ethidium bromide electron microscope mapping method. We find that the genes are interdigitated with spacer sequences of different lengths; that there are three coding sequences on pSp2, all on the same strand, with the relative order H1, H4, and B4; and that there are two coding sequences on pSp17, both on the same strand, corresponding to the messages denoted B1 and B2-B3, where B4, B1, and B2-3 are electrophoretically resolved components of histone mRNA, all of size intermediate between the larger H1 and the smaller H4 message.

Secondary structure in transfer RNA genes

The bacterial strand of the heteroduplex of λh80 dglyTsu+36tyrTthrT with λh80 carries a cluster of three transfer RNA genes. The bacterial strands of the heteroduplexes of φ80hpsu+,−III and φ80hpsu−III with φ80h carry two and one genes for tyrosine tRNA, respectively. When these heteroduplexes are spread under weakly denaturing conditions (low formamide), secondary structure features consisting of one or several closely clustered, short duplex regions (folds) are observed. The features map at the positions of the tRNA gene clusters. They are not seen if the DNA is hybridized to Escherichia coli tRNA. It is concluded that the secondary structure features are due to self-complementary sequences in the tRNA genes. In some cases, the duplex folds appear to involve base pairing between sequences on different tRNA genes of a cluster and may also involve the spacer sequences between the tRNA sequences.