Structure and mapping of the human thymopoietin (TMPO) gene and relationship of human TMPO beta to rat lamin-associated polypeptide 2.

Thymopoietins (TMPOs, previously abbreviated TPs) alpha (75 kDa), beta (51 kDa), and gamma (39 kDa) are related nuclear proteins expressed in many or all tissues. TMPO alpha is present diffusely throughout the nucleus, while TMPOs beta and gamma are localized to the nuclear membrane. Here we report the cloning and analysis of a single TMPO gene encoding TMPOs alpha, beta, and gamma, which are produced by alternative mRNA splicing, as previously inferred from cDNA sequences. The eight exons of the TMPO gene are spread over approximately 35 kb. Exon 4, which is spliced into TMPO alpha mRNA, contains sequences that encode a putative basic nuclear localization motif. Exon 8, which is spliced into TMPO beta and gamma mRNAs, encodes a hydrophobic putative membrane-spanning domain that is thought to target TMPOs beta and gamma to the nuclear membrane. TMPO beta appears to be the human homologue of the recently described rat protein LAP2 (lamina-associated polypeptide 2), which is thought to play an important role in the regulation of nuclear architecture by binding lamin B1 and chromosomes in a manner regulated by phosphorylation during mitosis (K. Furukawa and L. Gerace, La Jolla, pers. comm., 22 Nov. 1994). The human TMPO gene maps to chromosome band 12q22.

Transformation of a bop-hop-sop-I-sop-II-Halobacterium halobium mutant to bop+: effects of bacteriorhodopsin photoactivation on cellular proton fluxes and swimming behavior.

We have transformed Pho81, a Halobacterium halobium mutant strain which does not contain any of the four retinylidene proteins known in this species, with the bop gene cluster to create Pho81BR, a BR+HR-SR-I-SR-II-strain. The absorption spectrum, pigment reconstitution process, light-dark adaptation and photochemical reaction cycle of the expressed protein are indistinguishable from those of native bacteriorhodopsin (BR) in purple membrane of wild type strains. Strain Pho81BR permits for the first time characterization of effects of BR photoactivation alone on cell swimming behavior and energetics in the absence of the spectrally similar phototaxis receptor sensory rhodopsin I (SR-I) and electrogenic chloride pump halorhodopsin (HR). A non-adaptive upward shift in spontaneous swimming reversal frequency occurs following 3 s of continuous illumination of Pho81BR cells with green light (550 +/- 20 nm). This effect is abolished by low concentrations of the proton ionophore carbonylcyanide m-chlorophenylhydrazone. Although BR does not mediate phototaxis responses in energized Pho81BR cells under our culture conditions, proton pumping by BR in Pho81BR cells partially deenergized by inhibitors of respiration and adenosine triphosphate synthesis results in a small attractant response. Based on our measurements, we attribute the observed effects of BR photoactivation on swimming behavior to secondary consequences of electrogenic proton pumping on metabolic or signal transduction pathways, rather than to primary sensory signaling such as that mediated by SR-I. Proton extrusion by BR activates gated proton influx ports resulting in net proton uptake in wild-type cells.(ABSTRACT TRUNCATED AT 250 WORDS)

Transformation of members of the genus Haloarcula with shuttle vectors based on Halobacterium halobium and Haloferax volcanii plasmid replicons.

We have stably transformed both Haloarcula vallismortis and Haloarcula hispanica with the halobacterium-Escherichia coli shuttle vectors pWL102 (based on the Haloferax volcanii pHV2 replicon) and pUBP2 (based on the Halobacterium halobium pHH1 replicon). Haloferax volcanii, Halobacterium halobium, and Haloarcula vailismortis are equally distant from one another and span the phylogenetic depth of the halophilic Archaea; thus, these vectors may be generally useful for the halophiles. Both Haloarcula vallismortis and Haloarcula hispanica exhibit previously unreported complex life cycles and are therefore significant as genetically approachable models of cellular differentiation within the Archaea.

Transformation of the archaebacterium Halobacterium volcanii with genomic DNA.

We describe optimization of a transformation system for the halophilic archaebacterium Halobacterium volcanii. Transformation of spheroplasts in the presence of polyethylene glycol permits the uptake and expression of high-molecular-weight linear fragments of genomic DNA as well as plasmid or bacteriophage DNA. Transformations can be performed with either fresh or frozen cell preparations. Auxotrophic mutants were transformed to prototrophy with genomic DNA from wild-type cells with efficiencies of 5 x 10(4)/micrograms of DNA and frequencies of 8 x 10(-5) per regenerated spheroplast. The overall efficiency of transformation with genomic DNA implies that genetic recombination is an efficient process in H. volcanii.

Transformation methods for halophilic archaebacteria.

We present a practical description of polyethylene glycol mediated spheroplast transformation of Halobacterium halobium and Halobacterium volcanii. This method has been applied to phage DNA transfection, plasmid DNA transformation, and transformation with linear fragments of high molecular weight genomic DNA. Efficient spheroplast regeneration allows uncomplicated recovery of transformed progeny. Transformations can be performed equally well using fresh or frozen cell preparations. These methods should find application in molecular cloning, genetic fine mapping, and strain construction.

Characterization of pHV2 from Halobacterium volcanii and its use in demonstrating transformation of an archaebacterium.

We determined the complete nucleotide sequence of the 6354-base-pair plasmid pHV2 of the archaebacterium Halobacterium volcanii. This plasmid is present in approximately six copies per chromosome. We have generated a strain, H. volcanii WFD11, cured of pHV2 by treatment of liquid cultures with ethidium bromide. We describe PEG-mediated transformation of H. volcanii WFD11 with intact pHV2 and with a form of pHV2 marked by a 93-base-pair deletion generated in vitro.

Efficient transfection of the archaebacterium Halobacterium halobium.

We developed an efficient polyethylene glycol-mediated spheroplast transfection method for the extremely halophilic archaebacterium Halobacterium halobium. The 59-kilobase-pair linear phage phi H DNA molecule routinely produced between 5 X 10(6) and 2 X 10(7) transfectants per microgram of DNA. Between 0.5 and 1% of spheroplasts were transfected per microgram of luminal diameter H DNA. Under our conditions, survival and regeneration of H. halobium spheroplasts were also quite efficient, suggesting that this method will be useful for introducing other DNAs into these bacteria.

Actions of the anticodon arm in translation on the phenotypes of RNA mutants.

In previous publications, we have shown that it is practical to study the translational activity of tRNAs by replacement and alteration of the anticodon arm sequence of the genus on a plasmid clone. Experiments in which the anticodon arm sequence is transplanted between tRNA genes suggest that the translational activity is determined by these sequences. We have therefore made every variant of the anticodon loop and the three base-pairs of the stem proximal to the loop, in order to resolve the relation between the structure of Su7Am tRNATrp, and its function. All derivatives conserved the normal secondary structure of the molecule, which was known to be essential for translational activity. The probability of translation of the amber codon by these suppressors is measured in this work. This translational activity in vivo is rationalized in terms of data on the copy numbers of the plasmid clones, the nucleotide modifications of the tRNAs, the steady-state level of the mature tRNA, and the aminoacylation of these molecules. Nucleotide modification levels vary among these tRNAs, giving information about the specificities of modification systems that make O-methylribose, pseudouridine, and modified A in the anticodon arm. However, for this series of tRNAs, none of these modifications has a strong effect on translational efficiency of the tRNAs. A few of the substitutions reduce aminoacylation of the tRNAs with glutamine, as determined by comparison of suppression in normal strains and related strains, which have 25-fold elevated levels of the glutaminyl-tRNA synthetase (GlnRS). The substitutions that have the largest effect on GlnRS action are, unexpectedly, purines for conserved pyrimidines on the 5' side of the anticodon loop. Data on the concentrations of tRNA in vivo suggest that the anticodon loop and helix contribute similarly to the determination of the steady-state level of the tRNAs. This level varies sevenfold, though all tRNAs are processed from a homologous precursor made from the same transcription unit. Effects on levels appear to be mediated by changes in anticodon arm structure. A robust equation that relates aminoacyl-tRNA levels to suppressor efficiency is developed in order to resolve effects on tRNA levels and on ribosomal steps: E = A/(K + A), where E is efficiency, A is aminoacyl-tRNA concentration, and K is the effective concentration, or cellular tRNA content required for an individual tRNA to have an efficiency of 0.50. The tRNAs vary in their intrinsic ability to function on the ribosome (represented by K), after other influences have been normalized.(ABSTRACT TRUNCATED AT 400 WORDS)

Construction of a systematic set of tRNA mutants by ligation of synthetic oligonucleotides into defined single-stranded gaps.

A series of mutant tRNA genes has been constructed by site-directed mutagenesis in pOP203, a colE1 derivative carrying a transcription unit under control of the lacUV5 promoter. These mutant genes include all possible amber suppressing variants of tRNATrp with single nucleotide substitutions at anticodon loop positions 32, 37, and 38 (numbered from the 5' end), and all possible paired base substitutions in the three base pairs nearest the anticodon loop. G at position 38 was not recovered as a single mutation, but rather in conjunction with an undirected mutation to T at position 32. The singly mutated G38 tRNA may not be active, though all the other tRNA derivatives are functional in the translation of amber codons. To construct the mutants, we ligated a synthetic deoxyoligonucleotide into a precisely formed single-stranded gap covering the anticodon arm region DNA, in an otherwise double-stranded fragment containing the tRNATrp gene. The resulting heteroduplex was then ligated into the plasmid and introduced into Escherichia coli. This method of mutagenesis is simple, reproducible, and highly tolerant of varying degrees of heteroduplex in the gap, variations in temperature of ligation, and changes in the oligonucleotide concentration. Mutagenesis does not require a 5'-phosphorylated oligonucleotide. These qualities suit the gap method for intensive study of a region by site-directed mutagenesis.

Defined set of cloned termination suppressors: in vivo activity of isogenetic UAG, UAA, and UGA suppressor tRNAs.

We have cloned an isogenetic set of UAG, UAA, and UGA suppressors. These include the Su7 -UAG, Su7 -UAA, and Su7 -UGA suppressors derived from base substitutions in the anticodon of Escherichia coli tRNATrp and also Su9 , a UGA suppressor derived from a base substitution in the D-arm of the same tRNA. These genes are cloned on high-copy-number plasmids under lac promoter control. The construction of the Su7 -UAG plasmid and the wild-type trpT plasmid have been previously described ( Yarus , et al., Proc. Natl. Acad. Sci. U.S.A. 77:5092-5097, 1980). Su7 -UAA ( trpT177 ) is a weak suppressor which recognizes both UAA and UAG nonsense codons and probably inserts glutamine. Su7 -UGA ( trpT176 ) is a strong UGA suppressor which may insert tryptophan. Su9 ( trpT178 ) is a moderately strong UGA suppressor which also recognizes UGG (Trp) codons, and it inserts tryptophan. The construction of these plasmids is detailed within. Data on the DNA sequences of these trpT alleles and on amino acid specificity of the suppressors are presented. The efficiency of the cloned suppressors at certain nonsense mutations has been measured and is discussed with respect to the context of these codons.

The structure of the phi 80d3 ilv+ Su+7 transducing phage and the origin of its Su+7 tRNA-gene containing fragment.

The Bam HI, XhoI, and EcoRI sites of the transducing phage phi 80d3Su+7ilv+ are located. The 1.2 x 10(6) MD EcoRI fragment which, when cloned, contains tRNAAsp and expresses the mutant tRNATry gene, Su+7, and which also relaxes control of stable RNA synthesis is found immediately adjacent to the rrnC region. Its tRNA genes, tRNAAsp and tRNATry, are transcribed in the same direction as the ribosomal RNA genes, though no mature rRNA subsequences are on the fragment. This fragment also exists as such in another F-prime factor derived from the same Hfr host, and therefore presumably also in the Hfr chromosome itself. It is composed of about half ordinary chromosomal and half F DNA sequences, the latter from the gamma-delta region of F. The advantages of a novel mapping method used are discussed.