Introduction to plasmid biology.

An array of issues pertaining to plasmid biology are presented in this unit. Topics include replicators, an explanation of the mechanism of replication and copy-number control, plasmid incompatibility, selectable markers, cloning sites, and factors to consider when choosing a plasmid vector, whether it be for production of ssDNA, cloning of large inserts, or expression of large quantities of recombinant proteins. Considerations are discussed for the use of plasmids in yeast, cultured mammalian cells and non-E. coli bacteria. Finally, maps of many common useful plasmids are presented. This unit has recently been updated and extensively revised to include some of the latest developments in plasmid construction and experimental use.

The timing of lin-4 RNA accumulation controls the timing of postembryonic developmental events in Caenorhabditis elegans.

The lin-4 gene encodes a small RNA that is required to translationally repress lin-14 toward the end of the first larval stage of Caenorhabditis elegans development. To determine if the timing of LIN-14 protein down-regulation depends on the temporal profile of lin-4 RNA level, we analyzed the stage-specificity of lin-4 RNA expression during wild-type development and examined the phenotypes of transgenic worms that overexpress lin-4 RNA during the first larval stage. We found that lin-4 RNA first becomes detectable at approximately 12 h of wild-type larval development and rapidly accumulates to nearly maximum levels by 16 h. This profile of lin-4 RNA accumulation corresponded to the timing of LIN-14 protein down-regulation. Transgenic strains that express elevated levels of lin-4 RNA prior to 12 h of development display reduced levels of LIN-14 protein and precocious phenotypes consistent with abnormally early loss of lin-14 activity. These results indicate that the temporal profile of lin-4 RNA accumulation specifies the timing of LIN-14 down-regulation and thereby controls the timing of postembryonic developmental events.

The C. elegans heterochronic gene lin-4 encodes small RNAs with antisense complementarity to lin-14.

lin-4 is essential for the normal temporal control of diverse postembryonic developmental events in C. elegans. lin-4 acts by negatively regulating the level of LIN-14 protein, creating a temporal decrease in LIN-14 protein starting in the first larval stage (L1). We have cloned the C. elegans lin-4 locus by chromosomal walking and transformation rescue. We used the C. elegans clone to isolate the gene from three other Caenorhabditis species; all four Caenorhabditis clones functionally rescue the lin-4 null allele of C. elegans. Comparison of the lin-4 genomic sequence from these four species and site-directed mutagenesis of potential open reading frames indicated that lin-4 does not encode a protein. Two small lin-4 transcripts of approximately 22 and 61 nt were identified in C. elegans and found to contain sequences complementary to a repeated sequence element in the 3' untranslated region (UTR) of lin-14 mRNA, suggesting that lin-4 regulates lin-14 translation via an antisense RNA-RNA interaction.

High intensity and blue light regulated expression of chimeric chalcone synthase genes in transgenic Arabidopsis thaliana plants.

To establish a genetic system for dissection of light-mediated signal transduction in plants, we analyzed the light wavelengths and promoter sequences responsible for the light-induced expression of the Arabidopsis thaliana chalcone synthase (CHS) promoter fused to the beta-glucuronidase (GUS) marker gene. Transgenic A. thaliana lines carrying 1975, 523, 186, and 17 bp of the CHS promoter fused to the GUS gene were generated, and the expression of these chimeric genes was monitored in response to high intensity light in mature plants and to different wavelengths of light in seedlings. Fusion constructs containing 1975 and 523 bp of CHS promoter sequence behaved identically to the endogenous CHS gene under all conditions. Expression of these constructs was induced specifically in response to high intensity white light and blue light. The response to blue light was seen in the presence of the Pfr form of phytochrome. Fusion constructs containing 186 bp of promoter sequence showed reduced basal levels of expression and only weak stimulation by blue light but were induced significantly by high intensity white light. These analyses showed that the expression of the A. thaliana CHS gene is responsive to a specific blue light receptor and that sequences between -523 and -186 bp are required for optimal basal and blue light-induced expression of this gene. The experiments lay the foundation for a simple genetic screen for light response mutants.

Arabidopsis thaliana mutant that develops as a light-grown plant in the absence of light.

The signal transduction pathways that lead to chloroplast biogenesis in plants are largely unknown. We describe here the identification and initial characterization of a novel genetic locus which fits the criteria of a regulatory gene located in a central pathway controlling light-mediated development. In the absence of light, these Arabidopsis thaliana mutants, designated det1 (de-etiolated 1), constitutively display many characteristics that are light-dependent in wild-type plants, including leaf and chloroplast development, anthocyanin accumulation, and accumulation of mRNAs for several light-regulated nuclear and chloroplast genes. The switch between dark and light growth modes thus appears to be a programmed step in a developmental pathway that is defined by det1. We suggest a model where the primary role of light on gene expression is mediated by the activation of leaf development. Further, the recessive nature of the det1 mutation implies that there is negative growth control on leaf development in dicotyledonous plants in the absence of light.

Transcriptional regulation of the Arabidopsis thaliana chalcone synthase gene.

We have cloned an Arabidopsis thaliana chalcone synthase (CHS) gene on the basis of cross-hybridization with a Petroselinum hortense CHS cDNA clone. The protein sequence deduced from the A. thaliana CHS DNA sequence is at least 85% homologous to the CHS sequences from P. hortense, Antirrhinum majus, and Petunia hybrida. Southern blot analysis indicated that CHS is a single-copy gene in A. thaliana. High-intensity light treatment of A. thaliana plants for 24 h caused a 50-fold increase in CHS enzyme activity and an accumulation of visibly detectable levels of anthocyanin pigments in the vegetative structures of these plants. A corresponding increase in the steady-state level of CHS mRNA was detected after high-intensity light treatment for the same period of time. The accumulation of CHS mRNA in response to high-intensity light was due, at least in part, to an increased rate of transcription of the CHS gene as demonstrated by nuclear runoff experiments.

Developmental regulation of nodule-specific genes in alfalfa root nodules.

We have cloned alfalfa nodule-specific cDNAs that code for leghemoglobin (Lb), glutamine synthetase (GS), and three unidentified nodulins. Hybrid-select translation of nodule RNA followed by 2-D gel electrophoresis showed that the Lb-specific cDNA corresponded to at least four Lb species of 12 kDa. One of the unidentified cDNA clones (N-32/34) corresponded to at least five polypeptides of 32-34 kDa; a second unidentified cDNA clone (N-14) corresponded to an individual polypeptide of 14 kDa. The in vitro translation product(s) of the RNA hybrid selected by the third unidentified cDNA clone (N-22) formed a single band at 22 kDa on a one-dimensional gel. Northern and dot blot analyses of RNA isolated from wild-type nodules and from defective nodules elicited by a variety of Rhizobium meliloti mutants showed that 1) RNAs corresponding to the Lb, nodule-specific GS, and three unidentified nodulins were coordinately expressed during the course of nodule development, and 2) all five nodulins were expressed in Fix- nodules that contained infection threads and bacteroids but were not expressed in nodules that lacked infection threads and intracellular rhizobia.

Isofocusing of antigenic small nuclear ribonucleoproteins. I. Compositional analysis.

This report describes the behavior of antigenic small nuclear ribonucleoproteins (snRNPs) in native isofocusing gels. These RNA-protein complexes exhibited true isofocusing characteristics only when in the complexed form. Deproteinized snRNAs migrated to pH ranges which varied according to the pH of the application site. Immunological assays using lupus sera which recognized the La, Sm, and RNP determinants on these snRNPs established that the La and the Sm/RNP antigens segregated to pH 4.7-4.9 and 5.5-7.5, respectively. RNase digestion of these snRNPs did not alter the isofocusing migration of either the Sm or the La determinants. These antigenically active fractions contained the appropriate protein and RNA species shown by immunoprecipitation studies to associate with these antigenic determinants. The isofocusing fractions containing the uridylic acid-snRNPs were fully immunoprecipitable by anti-Sm sera, confirming their particulate integrity after isofocusing.

Isofocusing of antigenic small nuclear ribonucleoproteins. II. Preparative isolation.

In a companion report (T.B. Okarma, W.S. Schrier, and R. Feinbaum, 1985, Anal. Biochem. 147, 27-37) the behavior of small nuclear ribonucleoproteins (snRNPs) in native isofocusing gels was characterized. This communication extends those findings and describes a gentle procedure for the preparative isolation of snRNPs in native form from cultured murine L-5178y leukemia cells using sucrose density gradient centrifugation, preparative isofocusing, and gel filtration chromatography. Isofocusing in granulated gels separated intact uridylic acid (U)-snRNPs from tRNA and La RNPs. The U-snRNPs remained immunoprecipitable by lupus antisera throughout fractionation. The final product obtained in 2% yield contained primarily U1 and U2 snRNAs and lesser amounts of U3, U4, U5, and U6, along with the core U-snRNP polypeptides A-G. The core polypeptides displayed apparent pI's which ranged from 4.5 to 9.5 when analyzed by two-dimensional gel electrophoresis. Proteins B (28,000), D (16,000), and E (13,000) exhibited isoelectric variants. The Sm determinant proteins B' (28,000) and E (13,000) isofocused as basic peptides with apparent pI's of 9.5 and 8.5, respectively. The purity of the final fractions compared well with that of immunoprecipitates and the procedure reproducibly generated yields of native snRNPs sufficient for in vitro studies of their biological function.

Organization of the ribosomal ribonucleic acid genes in various wild-type strains and wild-collected strains of Neurospora.

The organization of the ribosomal DNA (rDNA) repeat unit in the standard wild-type strain of Neurospora crassa, 74-OR23-1A, and in 30 other wild-type strains and wild-collected strains of N. crassa, . tetrasperma, N. sitophila, N. intermedia, and N. discreta isolated from nature, was investigated by restriction enzyme digestion of genomic DNA, and probing of the Southern-blotted DNA fragments with specific cloned pieces of the rDNA unit from 74-OR23-1A. The size of the rDNA unit in 74-OR23-1A was shown to be 9.20 kilobase pairs (kb) from blotting data, and the average for all strains was 9.11 + 0.21 kb; standard error = 0.038; coefficient of variation (C.V.) = 2.34%. These data indicate that the rDNA repeat unit size has been highly conserved among the Neurospora strains investigated. However, while all strains have a conserved HindIII site near the 5' end of the 25 S rDNA coding sequence, a polymorphism in the number and/or position of HindIII sites in the nontranscribed spacer region was found between strains. The 74-OR23-1A strain has two HindIII sites in the spacer, while others have from 0 to at least 3. This restriction site polymorphism is strain-specific and not species-specific. It was confirmed for some strains by restriction analysis of clones containing most of the rDNA repeat unit. The current restriction map of the 74-OR23-1A rDNA repeat unit is presented.

GELYSIS: Pascal-implemented analysis of one-dimensional electrophoresis gels.

GELYSIS (GEL analYSIS) is a Pascal implementation of an algorithm that takes data on the distances migrated by DNA fragments in a one-dimension electrophoretic gel and calculates the sizes of the fragments based on the known sizes of marker fragments. A key step in the overall algorithm is a cubic-spline best-fit of marker calibration data. An option of the program is the generation of graphic representations of the gel and of the calibration spline that are convenient for primary data storage or for publication. Provision is made for specifying different band intensities in the graphic output of the gel.