Characterization of transcripts expressed from nitrogenase-3 structural genes of Azotobacter vinelandii

1992 ◽  
Vol 38 (9) ◽  
pp. 929-936 ◽  
Author(s):  
R. Premakumar ◽  
Marty R. Jacobson ◽  
Telisa M. Loveless ◽  
Paul E. Bishop
Keyword(s):  
Azotobacter Vinelandii ◽  
Coding Region ◽  
Base Pairs ◽  
S1 Nuclease ◽  
Mrna Species ◽  
Mutant Strains ◽  
S1 Nuclease Mapping ◽  
Alternative Nitrogenase ◽  
Nuclease Mapping

Five major anfH-hybridizing mRNA species accumulated in Azotobacter vinelandii cells derepressed for nitrogenase-3 (an alternative nitrogenase, which appears to lack Mo and V). Using anfH-, anfD-, anfG-, anfK-, and orf1orf2-specific probes and mutant strains of A. vinelandii these mRNA species have been identified as encoding anfHDGKorf1orf2 (6.0 kb), anfHDGK (4.3 kb), anfHD (2.6 kb), vnfHorfFd (1.3 kb), and vnfH and (or) anfH(1.0 kb). A 0.6-kb mRNA species, which hybridized only to the orf1orf2-specific probe, and a 3.5-kb mRNA species, which hybridized to anfD or anfK, also accumulated under these conditions. Northern blot analysis and S1 nuclease mapping indicate that transcription of the anf structural gene cluster initiates at a unique nif consensus promoter situated 127 base pairs upstream from the anfH coding region. Observation of anfH-hybridizing mRNA species that accumulate in strains derepressed for nitrogen fixation demonstrates that transcription of the anfHDGKorf1orf2 cluster is normally repressed by Mo, V, and NH4+, whereas transcription of the vnfHorfFd cluster does not require the presence of V and is repressed only by Mo, but not NH4+. Analysis of the accumulation of mRNAs in a tungsten-tolerant strain revealed that Mo and V repression of anf transcription must occur by different mechanisms. Key words: Azotobacter vinelandii, nitrogenase-3, transcripts, regulation, molybdenum, vanadium.

RAD3 gene of Saccharomyces cerevisiae: nucleotide sequence of wild-type and mutant alleles, transcript mapping, and aspects of gene regulation

1985 ◽  
Vol 5 (1) ◽  
pp. 17-26
Author(s):  
L Naumovski ◽  
G Chu ◽  
P Berg ◽  
E C Friedberg
Keyword(s):  
Saccharomyces Cerevisiae ◽  
Nucleotide Sequence ◽  
Coding Region ◽  
Base Pairs ◽  
S1 Nuclease ◽  
Calculated Molecular Weight ◽  
Base Pair Deletion ◽  
S1 Nuclease Mapping ◽  
Essential Function ◽  
Nuclease Mapping

We determined the complete nucleotide sequence of the RAD3 gene of Saccharomyces cerevisiae. The coding region of the gene contained 2,334 base pairs that could encode a protein with a calculated molecular weight of 89,796. Analysis of RAD3 mRNA by Northern blots and by S1 nuclease mapping indicated that the transcript was approximately 2.5 kilobases and did not contain intervening sequences. Fusions between the RAD3 gene and the lac'Z gene of Escherichia coli were constructed and used to demonstrate that the RAD3 gene was not inducible by DNA damage caused by UV radiation or 4-nitroquinoline-1-oxide. Two UV-sensitive chromosomal mutant alleles of RAD3, rad3-1 and rad3-2, were rescued by gap repair of a centromeric plasmid, and their sequences were determined. The rad3-1 mutation changed a glutamic acid to lysine, and the rad3-2 mutation changed a glycine to arginine. Previous studies have shown that disruption of the RAD3 gene results in loss of an essential function and is associated with inviability of haploid cells. In the present experiments, plasmids carrying the rad3-1 and rad3-2 mutations were introduced into haploid cells containing a disrupted RAD3 gene. These plasmids expressed the essential function of RAD3 but not its DNA repair function. A 74-base-pair deletion at the 3' end of the RAD3 coding region or a fusion of this deletion to the E. coli lac'Z gene did not affect either function of RAD3.

scholarly journals RAD3 gene of Saccharomyces cerevisiae: nucleotide sequence of wild-type and mutant alleles, transcript mapping, and aspects of gene regulation.

1985 ◽  
Vol 5 (1) ◽  
pp. 17-26 ◽  
Author(s):  
L Naumovski ◽  
G Chu ◽  
P Berg ◽  
E C Friedberg
Keyword(s):  
Saccharomyces Cerevisiae ◽  
Nucleotide Sequence ◽  
Coding Region ◽  
Base Pairs ◽  
S1 Nuclease ◽  
Calculated Molecular Weight ◽  
Base Pair Deletion ◽  
S1 Nuclease Mapping ◽  
Essential Function ◽  
Nuclease Mapping

We determined the complete nucleotide sequence of the RAD3 gene of Saccharomyces cerevisiae. The coding region of the gene contained 2,334 base pairs that could encode a protein with a calculated molecular weight of 89,796. Analysis of RAD3 mRNA by Northern blots and by S1 nuclease mapping indicated that the transcript was approximately 2.5 kilobases and did not contain intervening sequences. Fusions between the RAD3 gene and the lac'Z gene of Escherichia coli were constructed and used to demonstrate that the RAD3 gene was not inducible by DNA damage caused by UV radiation or 4-nitroquinoline-1-oxide. Two UV-sensitive chromosomal mutant alleles of RAD3, rad3-1 and rad3-2, were rescued by gap repair of a centromeric plasmid, and their sequences were determined. The rad3-1 mutation changed a glutamic acid to lysine, and the rad3-2 mutation changed a glycine to arginine. Previous studies have shown that disruption of the RAD3 gene results in loss of an essential function and is associated with inviability of haploid cells. In the present experiments, plasmids carrying the rad3-1 and rad3-2 mutations were introduced into haploid cells containing a disrupted RAD3 gene. These plasmids expressed the essential function of RAD3 but not its DNA repair function. A 74-base-pair deletion at the 3' end of the RAD3 coding region or a fusion of this deletion to the E. coli lac'Z gene did not affect either function of RAD3.

Transcription and processing of RNA from mouse ribosomal DNA transfected into hamster cells

1989 ◽  
Vol 9 (4) ◽  
pp. 1667-1671
Author(s):  
Raziuddin ◽  
R D Little ◽  
T Labella ◽  
D Schlessinger
Keyword(s):  
Gene Segment ◽  
State Level ◽  
Rrna Synthesis ◽  
Transcription Start ◽  
Base Pairs ◽  
S1 Nuclease ◽  
External Transcribed Spacer ◽  
S1 Nuclease Mapping ◽  
Nuclease Mapping ◽  
Entire Gene

Transcription of mouse genes coding for rRNA in CHO cells was promoter dependent at levels 3 to 10% of that of endogenous rRNA synthesis. Northern (RNA) and S1 nuclease mapping analyses demonstrated that transcription proceeds through the entire gene segment coding for rRNA in transfected constructs and continues, at least in some cases, into the adjoining plasmid sequences. S1 nuclease mapping also detected some processing cleavages in the transcripts, including those at the 3' terminus of 18S rRNA, those at the rapidly cleaved site at +650 in the external transcribed spacer, and those at a previously uncharacterized, rapidly cleaved site in the internal transcribed spacer. Deletion of sequences upstream or downstream from the promoter generally had no measurable effect on the level of transcription, but deletion of a 300-base-pair XhoI-XhoI fragment starting 1,287 base pairs from the transcription start site sharply increased the steady-state level of rRNA. Effects on processing were harder to test, because many intermediates are too unstable to detect even by S1 nuclease mapping; however, the data suggest that RNAs with deletions in the external transcribed spacer are processed poorly at distal sites. Processing at some sites may thus depend on interactions involving distant segments of rRNA.

scholarly journals Cloning and Characterization of SmeT, a Repressor of the Stenotrophomonas maltophilia Multidrug Efflux Pump SmeDEF

2002 ◽  
Vol 46 (11) ◽  
pp. 3386-3393 ◽  
Author(s):  
Patricia Sánchez ◽  
Ana Alonso ◽  
Jose L. Martinez
Keyword(s):  
Stenotrophomonas Maltophilia ◽  
Efflux Pump ◽  
Wild Type ◽  
Multidrug Efflux ◽  
Multidrug Efflux Pump ◽  
S1 Nuclease ◽  
Cellular Factor ◽  
S1 Nuclease Mapping ◽  
Nuclease Mapping

ABSTRACT We report on the cloning of the gene smeT, which encodes the transcriptional regulator of the Stenotrophomonas maltophilia efflux pump SmeDEF. SmeT belongs to the TetR and AcrR family of transcriptional regulators. The smeT gene is located upstream from the structural operon of the pump genes smeDEF and is divergently transcribed from those genes. Experiments with S. maltophilia and the heterologous host Escherichia coli have demonstrated that SmeT is a transcriptional repressor. S1 nuclease mapping has demonstrated that expression of smeT is driven by a single promoter lying close to the 5′ end of the gene and that expression of smeDEF is driven by an unique promoter that overlaps with promoter PsmeT. The level of expression of smeT is higher in smeDEF-overproducing S. maltophilia strain D457R, which suggests that SmeT represses its own expression. Band-shifting assays have shown that wild-type strain S. maltophilia D457 contains a cellular factor(s) capable of binding to the intergenic smeT-smeD region. That cellular factor(s) was absent from smeDEF-overproducing S. maltophilia strain D457R. The sequence of smeT from D457R showed a point mutation that led to a Leu166Gln change within the SmeT protein. This change allowed overexpression of both smeDEF and smeT in D457R. It was noteworthy that expression of wild-type SmeT did not fully complement the smeT mutation in D457R. This suggests that the wild-type protein is not dominant over the mutant SmeT.

scholarly journals Upstream activation of ribosomal RNA biosynthesis in Saccharomyces cerevisiae

1985 ◽  
Vol 232 (1) ◽  
pp. 205-209 ◽  
Author(s):  
R V Quincey ◽  
R E Godfrey
Keyword(s):  
Shuttle Vector ◽  
Initiation Site ◽  
Rrna Gene ◽  
Coding Region ◽  
S1 Nuclease ◽  
Mapping Procedure ◽  
Nontranscribed Spacer ◽  
S1 Nuclease Mapping ◽  
Yeast Transformants ◽  
Nuclease Mapping

Yeast was transformed with eight recombinants that contained an rRNA minigene and upstream elements of rDNA in different orientations in the multi-copy yeast-Escherichia coli shuttle vector, pJDB207. The effect of these elements of upstream rDNA on the initiation of transcription of the minigene at the site for rRNA biosynthesis was determined by using an S1 nuclease mapping procedure to measure the abundance of the minigene transcript in RNA from the yeast transformants. Transcription of the minigene was enhanced 3-fold by DNA within a 2.2 kb element more than 1.5 kb upstream from the initiation site. Inversion of the 2.2 kb element decreased expression of the minigene by 40%. This 2.2 kb element contained approx. 500 bp from the 25S rRNA coding region at the 3′ end of the preceding rRNA gene and 1 kb of adjacent nontranscribed spacer rDNA. The enhancing activity was independent of interference from readthrough that might have contributed to the 7-fold decrease in minigene expression caused by removing all rDNA upstream from −209 bp.

scholarly journals Transcription and processing of RNA from mouse ribosomal DNA transfected into hamster cells.

1989 ◽  
Vol 9 (4) ◽  
pp. 1667-1671 ◽  
Author(s):  
Raziuddin ◽  
R D Little ◽  
T Labella ◽  
D Schlessinger
Keyword(s):  
Gene Segment ◽  
State Level ◽  
Rrna Synthesis ◽  
Transcription Start ◽  
Base Pairs ◽  
S1 Nuclease ◽  
External Transcribed Spacer ◽  
S1 Nuclease Mapping ◽  
Nuclease Mapping ◽  
Entire Gene

Transcription of mouse genes coding for rRNA in CHO cells was promoter dependent at levels 3 to 10% of that of endogenous rRNA synthesis. Northern (RNA) and S1 nuclease mapping analyses demonstrated that transcription proceeds through the entire gene segment coding for rRNA in transfected constructs and continues, at least in some cases, into the adjoining plasmid sequences. S1 nuclease mapping also detected some processing cleavages in the transcripts, including those at the 3' terminus of 18S rRNA, those at the rapidly cleaved site at +650 in the external transcribed spacer, and those at a previously uncharacterized, rapidly cleaved site in the internal transcribed spacer. Deletion of sequences upstream or downstream from the promoter generally had no measurable effect on the level of transcription, but deletion of a 300-base-pair XhoI-XhoI fragment starting 1,287 base pairs from the transcription start site sharply increased the steady-state level of rRNA. Effects on processing were harder to test, because many intermediates are too unstable to detect even by S1 nuclease mapping; however, the data suggest that RNAs with deletions in the external transcribed spacer are processed poorly at distal sites. Processing at some sites may thus depend on interactions involving distant segments of rRNA.

scholarly journals Location of the initial cleavage sites in mouse pre-rRNA.

1983 ◽  
Vol 3 (8) ◽  
pp. 1501-1510 ◽  
Author(s):  
L H Bowman ◽  
W E Goldman ◽  
G I Goldberg ◽  
M B Hebert ◽  
D Schlessinger
Keyword(s):  
Blot Hybridization ◽  
Northern Blot Hybridization ◽  
28S Rrna ◽  
Cleavage Sites ◽  
S1 Nuclease ◽  
5.8S Rrna ◽  
Initial Cleavage ◽  
S1 Nuclease Mapping ◽  
Mapping Techniques ◽  
Nuclease Mapping

The locations of three cleavages that can occur in mouse 45S pre-rRNA were determined by Northern blot hybridization and S1 nuclease mapping techniques. These experiments indicate that an initial cleavage of 45S pre-rRNA can directly generate the mature 5' terminus of 18S rRNA. Initial cleavage of 45S pre-rRNA can also generate the mature 5' terminus of 5.8S rRNA, but in this case cleavage can occur at two different locations, one at the known 5' terminus of 5.8S rRNA and another 6 or 7 nucleotides upstream. This pattern of cleavage results in the formation of cytoplasmic 5.8S rRNA with heterogeneous 5' termini. Further, our results indicate that one pathway for the formation of the mature 5' terminus of 28S rRNA involves initial cleavages within spacer sequences followed by cleavages which generate the mature 5' terminus of 28S rRNA. Comparison of these different patterns of cleavage for mouse pre-rRNA with that for Escherichia coli pre-rRNA implies that there are fundamental differences in the two processing mechanisms. Further, several possible cleavage signals have been identified by comparing the cleavage sites with the primary and secondary structure of mouse rRNA (see W. E. Goldman, G. Goldberg, L. H. Bowman, D. Steinmetz, and D. Schlessinger, Mol. Cell. Biol. 3:1488-1500, 1983).

Multiple calmodulin mRNA species are derived from two distinct genes

1987 ◽  
Vol 7 (5) ◽  
pp. 1873-1880
Author(s):  
H Nojima ◽  
K Kishi ◽  
H Sokabe
Keyword(s):  
Dna Sequences ◽  
Northern Blotting ◽  
Amino Acid Sequences ◽  
Cdna Clones ◽  
Rat Tissues ◽  
Coding Region ◽  
Genomic Libraries ◽  
Mrna Species ◽  
Nuclease Mapping ◽  
Rat Genome

We have observed three calmodulin mRNA species in rat tissues. In order to know from how many expressed genes they are derived, we have investigated the genomic organization of calmodulin genes in the rat genome. From a rat brain cDNA library, we obtained two kinds of cDNAs (pRCM1 and pRCM3) encoding authentic calmodulin. DNA sequence analysis of these cDNA clones revealed substitutions of nucleotides at 73 positions of 450 nucleotides in the coding region, although the amino acid sequences of these calmodulins are exactly the same. DNA sequences in the 5' and 3' noncoding regions are quite different between these two cDNAs. From these results, we conclude that they are derived from two distinct bona fide calmodulin genes, CaMI (pRCM1) and CaMII (pRCM3). Total genomic Southern hybridization suggested four distinct calmodulin-related genes in the rat genome. By cloning and sequencing the calmodulin-related genes from rat genomic libraries, we demonstrated that the other two genes are processed pseudogenes generated from the CaMI (lambda SC9) and CaMII (lambda SC8) genes, respectively, through an mRNA-mediated process of insertions. Northern blotting showed that the CaMI gene is transcribed in liver, muscle, and brain in similar amounts, whereas the CaMII gene is transcribed mainly in brain. S1 nuclease mapping indicated that the CaMI gene produced two mRNA species (1.7 and 4 kilobases), whereas the CaMII gene expressed a single mRNA species (1.4 kilobases).

Location of the initial cleavage sites in mouse pre-rRNA

1983 ◽  
Vol 3 (8) ◽  
pp. 1501-1510
Author(s):  
L H Bowman ◽  
W E Goldman ◽  
G I Goldberg ◽  
M B Hebert ◽  
D Schlessinger
Keyword(s):  
Blot Hybridization ◽  
Northern Blot Hybridization ◽  
28S Rrna ◽  
Cleavage Sites ◽  
S1 Nuclease ◽  
5.8S Rrna ◽  
Initial Cleavage ◽  
S1 Nuclease Mapping ◽  
Mapping Techniques ◽  
Nuclease Mapping

The locations of three cleavages that can occur in mouse 45S pre-rRNA were determined by Northern blot hybridization and S1 nuclease mapping techniques. These experiments indicate that an initial cleavage of 45S pre-rRNA can directly generate the mature 5' terminus of 18S rRNA. Initial cleavage of 45S pre-rRNA can also generate the mature 5' terminus of 5.8S rRNA, but in this case cleavage can occur at two different locations, one at the known 5' terminus of 5.8S rRNA and another 6 or 7 nucleotides upstream. This pattern of cleavage results in the formation of cytoplasmic 5.8S rRNA with heterogeneous 5' termini. Further, our results indicate that one pathway for the formation of the mature 5' terminus of 28S rRNA involves initial cleavages within spacer sequences followed by cleavages which generate the mature 5' terminus of 28S rRNA. Comparison of these different patterns of cleavage for mouse pre-rRNA with that for Escherichia coli pre-rRNA implies that there are fundamental differences in the two processing mechanisms. Further, several possible cleavage signals have been identified by comparing the cleavage sites with the primary and secondary structure of mouse rRNA (see W. E. Goldman, G. Goldberg, L. H. Bowman, D. Steinmetz, and D. Schlessinger, Mol. Cell. Biol. 3:1488-1500, 1983).

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