Genetic mapping of genes required for motility in Caulobacter crescentus.

Mutations in more than 30 genes affect motility in Caulobacter crescentus. We have determined the chromosomal map locations for 27 genes involved in flagellar morphogenesis (fla), three genes involved in flagellar function (mot), and three genes that have a pleiotropic effect on both motility and bacteriophage resistance (ple). Three multigene clusters have been detected at widely separated chromosomal locations, but in addition, there are 12 fla and mot genes that are found at eight additional sites scattered around the C. crescentus chromosome. Thus, there is more scatter of genes involved in flagellar structure and function than has been observed in other bacterial systems.

General nonchemotactic mutants of Caulobacter crescentus.

We have examined 35 mutants that have defects in general chemotaxis. Genetic analysis of these mutants resulted in the identification of at least eight che genes located at six different positions on the Caulobacter crescentus chromosome. The cheR, cheB and cheT genes appeared to be located in a three-gene cluster. Mutations in these three genes resulted in the inability of the flagellum to reverse the direction of rotation. Defects in the cheR gene resulted in a loss of the ability to methylate the methyl-accepting chemotaxis proteins. In vitro experiments showed that the lack of in vivo methylation in cheR mutants was due to the absence of methyltransferase activity. Defects in the cheB gene resulted in greatly reduced chemotaxis-associated methylation in vivo and a loss of methylesterase activity in vitro. The specific defects responsible for the lack of a chemotactic response have not been determined for the other identified che genes.

Use of pulsed-field-gradient gel electrophoresis to construct a physical map of the Caulobacter crescentus genome.

The restriction enzyme DraI cleaves the Caulobacter crescentus genome into at least 35 fragments which have been resolved in agarose gels using pulsed-field-gradient gel electrophoresis (PFGE). When digests were performed using DNA from strains containing Tn5 insertion mutations, altered band migrations were observed. Using PFGE with the appropriate pulse times, size differences as small as 2% could be resolved in large fragments. Using this approach, we have constructed a partial physical map of the genome which correlates well with the C. crescentus genetic map and have shown the size of the genome to be approx. 3800 kb. Using hybridization with cloned genes, we have determined the map locations of five previously unmapped genes. In addition, we have shown that PFGE can be used to rapidly determine the map locations of new insertion mutations or the sizes of deletion mutations.

Genetic evidence for similar negative regulatory domains in the yeast transcription activators GAL4 and LAC9.

The GAL4 protein of Saccharomyces cerevisiae and the LAC9 protein of Kluyveromyces lactis are transcription activator proteins with similar structure and function. Greatest similarity occurs in the C region near the carboxy terminus, where 16 of 18 amino acids are identical. The function of the C region is unclear. Here we show that the structural similarity is reflected in functional similarity. Single amino acid changes in the C region of GAL4 and LAC9 create a similar phenotype: constitutive gene expression. In S. cerevisiae the constitutive phenotype caused by GAL4 mutants can be abolished by overproduction of GAL80. These results support a model in which the C region of GAL4 and LAC9 constitute similar negative regulatory domains that interact with GAL80 in S. cerevisiae and an unidentified GAL80 homolog in K. lactis. This protein-protein interaction prevents expression of the galactose operon in the uninduced state.

Circularity of the Caulobacter crescentus chromosome determined by pulsed-field gel electrophoresis.

Previous genetic analyses of the Caulobacter crescentus chromosome have resulted in the construction of a linear genetic map. To establish the circularity of the C. crescentus chromosome, restriction fragments generated by digestion with AseI and SpeI were analyzed by pulsed-field gel electrophoresis and Southern hybridization. The size of each fragment was calculated and used to demonstrate that C. crescentus has a genome size of approximately 4,000 kilobases. In addition, both enzymes gave rise to large DNA fragments which contained genes from both ends of the genetic map. Thus, there is physical linkage between the genes at the ends of the genetic map and the chromosome is circular. Since this region of the chromosome appears to contain the replication terminus, we propose that recombination occurs at a high frequency in the vicinity of the terminus. This high frequency of recombination would prevent genetic linkage from being observed between genes on opposite sides of the terminus. Additional experiments using insertions which introduced new AseI and DraI restriction sites into the genome allowed us to calculate the physical distance between genes located in the vicinity of the replication terminus.

Sequence conservation in the Saccharomyces and Kluveromyces GAL11 transcription activators suggests functional domains.

Efficient transcription of many Saccharomyces cerevisiae genes requires the GAL11 Protein. GAL11 belongs to a class of transcription activator that lacks a DNA-binding domain. Such proteins are thought to activate specific genes by complexing with DNA-bound proteins. To begin to understand the domain structure-function relationships of GAL11 we cloned and sequenced a homologue from the yeast Kluyveromyces lactis, Kl-GAL11. The two predicted GAL11 proteins show high overall amino acid conservation and an unusual amino acid composition including 18% glutamine, 10% asparagine (S. cerevisiae) or 7% (K. lactis), and 8% proline (K. lactis) or 5% (S. cerevisiae) residues. Both proteins have runs of pure glutamines. Sc-GAL11 has glutamine-alanine runs but in Kl-GAL11 the alanines in such runs are replaced by proline and other residues. The primary sequence similarity is reflected in functional similarity since a gal11 mutation in K. lactis creates phenotypes similar to those seen previously in gal11-defective S. cerevisiae. In addition, Kl-GAL11 complements a gal11-defect in S. cerevisiae by partially restoring induction of GAL1 expression, growth on nonfermentable carbon sources, and phosphorylation of GAL4.

Genetic mapping with Tn5-derived auxotrophs of Caulobacter crescentus.

Chromosomal insertions of Tn5 in Caulobacter crescentus displayed complete stability upon transduction and proved useful in strain building on complex media. RP4-primes constructed in vitro containing C. crescentus genomic sequences in the HindIII site of the kanamycin resistance gene failed to show enhanced or directed chromosome mobilization abilities. One of these kanamycin-sensitive RP4 derivatives, pVS1, was used as a mobilization vector in conjugation experiments on complex media where chromosomal Tn5 transfer to the recipient was selected. pVS1-mediated transfer of Tn5-induced auxotrophic mutations occurred at frequencies of 10(-6) to 10(-8) per donor cell. During conjugation with Tn5-encoded kanamycin resistance as the selected marker, Tn5 remained in its donor-associated locus in 85 to 100% of the transconjugants. A collection of eight temperature-sensitive donor strains bearing Tn5 insertion mutations from various regions of the C. crescentus genetic map were used to provide a rapid means for the determination of the map location of a new mutation. Use of the techniques described in this paper allowed an expansion of the C. crescentus genetic map to include the relative locations of 32 genes.

Structure of the mouse Saa4 gene and its linkage to the serum amyloid A gene family.

The serum amyloid A (SAA) proteins are a polymorphic family of apolipoproteins associated with high-density lipoproteins (HDL). Three distinct subfamilies have been identified: (i) a cytokine-induced acute phase subfamily that is hepatically produced and can become the major apolipoprotein on HDL (SAA1, SAA2); (ii) a peripherally produced acute phase SAA3 that is only a minor HDL apolipoprotein; and (iii) a constitutive subfamily (SAA4) that is a minor normal HDL apolipoprotein comprising more than 90% of the SAA during homeostasis. Here we define the structure of the Saa4 gene. Similar to other Saa family members, it has four exons and three introns. It is 4588 bp long from the transcription start site to the end of the 3'-untranslated region and is approximately 20% larger than other Saa genes. We have located Saa4 11 kb upstream from Saa3 and 5 kb downstream from Saa1, with the pseudogene approximately 1 kb from the 5' end of Saa4. Saa4 has the same orientation as most other Saa family members, with only Saa2 having an opposing orientation. These data promote our understanding of the evolution of the Saa family. They enhance our ability to develop the mouse as a transgenic and gene deletion model to advance the understanding of the function of these apolipoproteins.