The bacteriorhodopsin gene

The bacteriorhodopsin gene has been identified in a 5.3-kilobase restriction endonuclease fragment isolated from Halobacterium halobium DNA, using a cloned cDNA fragment as the probe. Of the 1229 nucleotides whose sequence was determined in the genomic fragment, 786 correspond to the structural gene of bacteriorhodopsin, 360 are upstream from the initiator methionine codon, and 83 are downstream from the COOH terminus. The bacteriorhodopsin gene codes for a precursor sequence of 13 amino acids at the NH2 terminus, 248 amino acids that are present in the mature protein and an additional aspartic acid at the COOH terminus. This determination of the DNA sequence for an archaebacterial gene reveals that the standard genetic code is used; however, there is a marked preference for either G or C in the third codon position. The gene does not contain any intervening sequences and no prokaryotic promoter can be identified in the region immediately upstream from the structural gene. The bacteriorhodopsin mRNA contains at the 5' terminus only three nucleotides beyond the initiating AUG codon and this terminus can form a hairpin structure. Immediately downstream from this structure there is a sequence complementary to the 3' terminus of H. halobium 16S rRNA.     

Covalent crosslinking of tRNA1Val to 16S RNA at the ribosomal P site: identification of crosslinked residues.

N-Acetylvalyl-tRNA1Val (AcVal-tRNA1Val) was bound to the P site of uniformly 32P-labeled 70S ribosomes from Escherichia coli and crosslinked to 16S RNA in the 30S ribosomal subunit by irradiation with light of 300-400 nm. To identify the crosslinked nucleotide in 16S RNA. AcVal-tRNA1Val-16S [32P]RNA was digested completely with RNase T1 and the band containing the covalently attached oligonucleotides from tRNA and rRNA was isolated by polyacrylamide gel electrophoresis. The crosslinked oligonucleotide, and the 32P-labeled rRNA moiety released from it by photoreversal of the crosslink at 254 nm, were then analyzed by secondary hydrolysis with pancreatic RNase A and RNase U2.The oligonucleotide derived from 16S RNA was found to be the evolutionarily conserved sequence, U-A-C-A-C-A-C-C-G1401, and the nucleotide crosslinked to tRNA1Val, C1400. The identity of the covalently attached residue in the tRNA was established by using AcVal-tRNA1Val-16S RNA prepared from unlabeled ribosomes. This complex was digested to completion with RNase T1 and the resulting RNA fragments were labeled at the 3' end with [5'-32P]pCp. The crosslinked T1 oligonucleotide isolated from the mixture yielded one major end-labeled component upon photoreversal. Chemical sequence analysis demonstrated that this product was derived from the anticodon-containing pentadecanucleotide of tRNA1Val, C-A-C-C-U-C-C-C-U-cmo5U-A-C-m6A-A-G39(cmo5U, 5-carboxymethoxyuridine). A similar study of the crosslinked oligonucleotide revealed that the residue covalently bound to 16S was cmo5U34, the 5' or wobble base of the anticodon. The adduct is believed to result from formation of a cyclobutane dimer between cmo5U34 of tRNA1Val and C1400 of the 16S RNA.     

Insertion of a repetitive element at the same position in the 5''-flanking regions of two dissimilar yeast tRNA genes.

The regions 5' proximal to many yeast tRNA genes exhibit a high frequency of DNA sequence polymorphisms. DNA sequence analysis of polymorphic variants of SUQ5, a tRNA Ser UCA gene, and SUP2, a tRNA Tyr gene, shows that in each case one sequence variant of the tRNA gene is 346 base pairs longer than the other. The longer variants appear to have arisen from the shorter ones by the insertion of nearly identical copies of a 341-base pair sigma element into a site 16 base pairs upstream from the 5' ends of the tRNA-coding regions. The sequences of the two copies of the sigma element differ at only five positions. The element has a number of properties that are typical of many transposable elements: (i) there is a perfect eight-base-pair inverted repeat at its ends, (ii) these ends are flanked by a five-base-pair direct repeat of a sequence that occurs only once in the target DNA, (iii) there are approximately 20 copies of the element in the yeast genome, and (iv) there is considerable strain-to-strain variation in the sizes of the restriction fragments on which these copies lie. The presence of the sigma element has no gross effect on the phenotype of a SUP2 ochre suppressor. Analysis of the SUQ5 and SUP2 sequences favors the hypothesis that sigma is a transposable element with a novel type of insertion specificity, which is primarily based on the presence of a tRNA-coding region a fixed distance from the insertion site, rather than on the immediate target sequences.     

Presence of bacterial 16S ribosomal RNA gene segments in human intestinal lymph follicles

BACKGROUND: There is currently no information regarding microbial agents inside the intestinal lymph follicles. METHODS: Biopsy or resected specimens, mostly from macroscopically normal areas, were sectioned with a cryostat. DNA was extracted from microdissected samples, exclusively from the lymph follicle. Amplification of DNA was performed using universal primers designed from conserved regions of bacterial 16S ribosomal RNA (rRNA). Several clones with inserts of around 400 base pairs were subjected to DNA sequence analysis followed by a database homology search. RESULTS: Bacterial 16S rRNA gene segments were detected in the lymph follicle in 2 of 14 (14%) non-inflammatory bowel disease (IBD) cases, 4 of 14 (28%) Crohn disease cases, and in 2 of 5 (40%) ulcerative colitis cases. Nineteen 16S rRNA gene segments were recognized in the eight positive cases. Five segments showed 100% identity to known bacterial 16S rRNAs, namely staphylococcus species, Streptococcus sanguis, and Paracoccus marcusii. However, the other 14 segments showed below 100% identity, indicating either the presence of unknown bacteria or of bacteria without known DNA data. No single identified or unidentified bacterium, characteristic of IBD, including Mycobacterium paratuberculosis and Listeria monocytogenes, was detected. CONCLUSIONS: The present study confirms the presence of bacterial 16S rRNA gene segments in human intestinal lymph follicles and paves the way for new investigations into the microbiology of the lymph follicle. Whether or not bacteria inside the lymph follicle is a primary stimulus in IBD has yet to be clarified.     

Complete nucleotide sequence of a 23S ribosomal RNA gene from Escherichia coli.

The complete nucleotide sequence of the 23S RNA gene from the rrnB operon of Escherichia coli has been determined. The sequences of both strands of the entire gene were determined, most of the sequence was independently confirmed by use of alternate restriction fragments, and all restriction cuts overlapped. The DNA region corresponding to mature 23S rRNA contains 2904 nucleotides. Kethoxal-reactive sites protected by 30S subunits are found between positions 2300 and 28000, placing the subunit interface in this region of the molecule. The functional importance of this region is further supported by studies by other investigators, including homology with chloroplast and mitochondrial rRNA.     

Cloning immunoglobulin gamma 2b chain gene of mouse: characterization and partial sequence determination.

DNA from newborn mice was digested with restriction endonuclease EcoRI, and a 6.6-kilobase fragment encoding immunoglobulin gamma 2b chain mRNA derived from MPC 11 myeloma was enriched about 100-fold by RPC-5 column chromatography and agarose gell electrophoresis. The 6.6-kilobase fragment was cloned with lambda gt WES.lambda B as EK2 vector. The cloned phage (lambda WES.IgH22) contained the constant region gene of the gamma 2b chain but not the variable region gene of MPC 11 mRNA. The constant region genes of the other gamma chains (i.e., gamma 1, gamma 2a, and gamma 3) were not present in lambda gt WES.IgH22 DNA. R-loop mapping indicates that the gamma 2b chain structural gene is divided into two parts (330 +/- 60 SD base pairs and 930 +/- 110 SD base pairs) by an intervening sequence (360 +/- 100 SD base pairs). The nucleotide sequence around the junction of the hinge region and CH2 domain was determined and shown to match the amino acid sequence of the initial part of the CH2 domain of the gamma 2b chain. The base sequence upstream from the junction, however, is unrelated to the amino acid sequence of the CH1 domain and the hinge region of all the gamma chains whose sequences have been determined. These results indicate that the gamma 2b chain gene is interrupted at the junction of the hinge region and CH2 domain by an intervening sequence. The existence of two more intervening sequences, one between the CH1 domain and the hinge region and the other between the CH2 and CH3 domains, is discussed.     

In vivo double-strand breaks occur at recombinogenic G + C-rich sequences in the yeast mitochondrial genome.

An optional 46-base-pair G + C-rich element (GC cluster) in the coding region of the yeast mitochondrial var1 gene inserts preferentially in crosses into recipient alleles that lack the sequence. Unlike a similar gene conversion event involving the insertion of an optional 1143-base-pair intron, the mitochondrial 21S rRNA gene, which requires the action of a protein encoded by a gene within that intron, conversion of the var1 GC cluster does not require any protein product of the mitochondrial genome. We have detected double-strand breaks in the var1 gene in mitochondrial DNA isolated from unmated haploid rho+ and rho- strains at or near the boundaries of the optional GC cluster, as well as at a conserved copy of that sequence 160 base pairs upstream. No double-strand breaks were detected in the recipient var1 DNA molecules in the vicinity of the optional GC cluster target sequence. This contrasts with 21S rRNA-encoding DNA (rDNA) intron conversion where the recipient, but not the donor DNA, is cleaved at the element insertion site. These results suggest that although the 21S rDNA intron and the var1 GC cluster are preferentially inserted into their respective short alleles, these conversions probably occur by different mechanisms.     

Suppressor of yeast mitochondrial ochre mutations that maps in or near the 15S ribosomal RNA gene of mtDNA.

A polypeptide chain-terminating mutation in the yeast mitochondrial oxi 1 gene has been shown to be an ochre (TAA) mutation by DNA sequence analysis. Mitochondrially inherited revertants of this mutation include two types: In the first, the ochre codon has been changed to a sense codon by further mutation in the oxi 1 gene while, in the second, the ochre codon is still present, indicating the occurrence of an extrageneic ochre suppressor mutation. This mitochondrial ochre suppressor, termed MSU1, has been "cloned" in rho- strains of yeast and tested against other oxi 1 mutations. Several additional mutations are also suppressible, and those examined so far are also ochre mutations. MSU1 does not suppress known frameshift or missense mutations at oxi 1. Isoelectric focusing of the gene product (cytochrome oxidase subunit II) from a suppressed-mutant strain indicates that suppression does not involve insertion of charged amino acids. Physical mapping of the mtDNA retained in the MSU1-carrying rho- clones localizes the suppressor mutation to the gene coding the 15S rRNA or a site not more than 300 base pairs from it. No known tRNA genes occur this close to the 15S rRNA gene, and mtDNA from a suppressor-carrying rho- does not hybridize detectably to mitochondrial tRNAs. These results suggest that MSU1 may be an alteration in the 15S rRNA.     

Use of gene 32 protein staining of single-strand polynucleotides for gene mapping by electron microscopy: application to the phi80d3ilvsu+7 system.

A method for visualizing RNA-DNA duplex regions along a single strand of DNA in the electron microscope is described. A preparation of RNA molecules is hybridized to a long DNA strand containing the coding sequences (genes) for some of the RNAs. T4 gene 32 protein, which binds selectively and cooperatively only to the single-strand regions, is added, followed by glutaraldehyde. The resulting nucleic acid-gene 32 complex is adsorbed to the surface of an electron microscope grid in the presence of ethidium bromide. The single-strand regions are relatively thick (8.5 nm) compared to the duplex (RNA-DNA hybrid) regions (3.5 nm), so that the two kinds of regions are readily recognized by electron microscopy. In favorable cases, tRNA-DNA hybrids of length about 80 nucleotide pairs can be recognized (although with difficulty). The positions of a number of interesting genetic sequences on the DNA of the transducing phage phi80d3ilvsu+7 have been mapped. The r strand contains 16S, 23S, and 5S rRNA coding sequences in that order. The spacer between 16S and 23S genes has a length of 500 nucleotides and contains the coding sequence for a tRNA2Glu gene in agreement with previous biochemical observations. The spacer between the 23S and 5S genes has a length of 180 nucleotides. The su+7 tRNATrp coding sequence has been mapped on the l strand at a position just to the left of the ilv genes. Secondary structure loops due to short inverted repeat sequences flanking the 16S, 23S, tRNATrp, and F sequences in the DNA have been observed.     

Characterization of a programmed alteration in an 18S ribosomal gene that accompanies the experimental induction of drug resistance in Schistosoma mansoni.

Stable resistance to the anthelmintic hycanthone can be produced in the human blood fluke Schistosoma mansoni by exposing immature parasites in mice to the drug. Within a single generation, genomic rearrangements, detected as rRNA-encoding DNA restriction fragment length polymorphisms (RFLPs), accompany the appearance of resistance in this model. One of these RFLPs, an approximately 3.6-kilobase BamHI fragment, was shown previously to associate consistently with resistance in independent generations of the JHU strain of S. mansoni. To characterize the genetic changes responsible for this RFLP, the fragment was cloned and sequenced. A comparison of the cloned fragment with a normal 18S rRNA gene demonstrated that the drug resistance-associated RFLP fragment arises through the addition of 732 base pairs into an 18S rRNA gene, 134 base pairs downstream of the junction of the intergenic spacer and the mature 18S rRNA gene. The mutation is nonrandom, targets one, or a few only, of the 100 or so copies of the ribosomal genes, and may represent the incomplete duplication of the gene since the inserted element is identical in sequence to the region contiguous to it. The sequence spanning the junction of the insertion and the original 18S rRNA gene was used as a specific primer for the BamHI RFLP in PCR experiments. The analysis conclusively demonstrated that the mutation is induced rather than selected by the drug since the junctional sequence was not detectable in the drug-sensitive parent population of schistosomes. In addition, analysis of four, independently derived, resistant lines indicated that the same region of the gene was mutated each time. Together, these data demonstrate that reproducible changes are induced during the acquisition of resistance in schistosomes and suggest that the resistant phenotype is induced rather than selected from preexisting forms.