Competence For Natural Transformation Research Articles

Prepilin-like molecules in type 4 pilus biogenesis: minor subunits, chaperones or mediators of organelle translocation?

identity across diverse species boundaries, have been proposed to be part of similar apparatuses for extracellular protein localization. These include genes encoding type 4 prepilin-like polypeptides, peptidases responsible for amino-terminal processing of the prepilin homologues, proteins peripherally associated with the cytoplasmic membrane with highly conserved nucleosidetriphosphate-binding (NTP-binding) sites, and outer-membrane proteins. Homologues corresponding to one or more of these families have been implicated in the extracellular localization of toxins and hydrolases by Gram-negative bacteria. Collectively, this has been termed the type II system: the two-step protein-export system or the general secretion pathway (GSP)‘. Related components are also essential for filamentous phage morphogenesis! and for the proper construction, localization and function of a DNAbinding and -uptake apparatus associated with competence for natural transformation in Bacillus subtilis’ and Haemophilus influenzaes. For all of these systems, the goal of research has been to understand how a structure analogous to type 4 pili, or events related to pilus biogenesis, might link these varied processes. I would like to suggest that perhaps we should look at the situation from the other point of view, and examine what studies of the GSP might reveal about type 4 pilus biogenesis.

Role of pili and the phase-variable PilC protein in natural competence for transformation of Neisseria gonorrhoeae.

The Gram-negative bacterial pathogen Neisseria gonorrhoeae is naturally competent for transformation with species-related DNA. We show here that two phase-variable pilus-associated proteins, the major pilus subunit (pilin, or PilE) and PilC, a factor known to function in the assembly and adherence of gonococcal pili, are essential for transformation competence. The PilE and PilC proteins are necessary for the conversion of linearized plasmid DNA carrying the Neisseria-specific DNA uptake signal into a DNase-resistant form. The biogenesis of typical pilus fibers is neither essential nor sufficient for this process. DNA uptake deficiency of defined piliated pilC1,2 double mutants can be complemented by expression of a cloned pilC2 gene in trans. The PilC defect can also be restored by the addition of purified PilC protein, or better, pili containing PilC protein, to the mutant gonococci. Our data suggest that the two phase-variable Pil proteins act on the bacterial cell surface and cooperate in DNA recognition and/or outer membrane translocation.

Spontaneous mutations in pcaH and -G, structural genes for protocatechuate 3,4-dioxygenase in Acinetobacter calcoaceticus

Bacteria containing spontaneous null mutations in pcaH and -G, structural genes for protocatechuate 3,4-dioxygenase, were selected by exposure of an Acinetobacter calcoaceticus strain to physiological conditions in which expression of the genes prevents growth. The parental bacterial strain exhibits high competence for natural transformation, and this procedure was used to characterize 94 independently isolated spontaneous mutations. Four of the mutations were caused by integration of a newly identified insertion sequence, IS1236. Many (22 of 94) of the mutations were lengthy deletions, the largest of which appeared to eliminate at least 17 kb of DNA containing most of the pca-qui-pob supraoperonic gene cluster. DNA sequence determination revealed that the endpoints of four smaller deletions (74 to 440 bp in length) contained DNA sequence repetitions aligned imprecisely with the sites of mutation. Analysis of direct and inverted DNA sequence repetitions associated with the sites of mutation suggested the existence of DNA slippage structures that make unhybridized nucleotides particularly susceptible to mutation.

Physiological regulation of competence induction for natural transformation in Acinetobacter calcoaceticus

Acinetobacter calcoaceticus induced competence for natural transformation maximally after dilution of a stationary culture into fresh medium. Competence was gradually lost during prolonged exponential growth and after entrance into the stationary state. Growth cessation and nutrient upshift were involved in the induction of competence. The level of competence of a chemostat culture of A. calcoaceticus was dependent on the nature of the growth limitation. Under potassium limitation a transformation frequency of ±1x10-4 was obtained. This frequency was independent of the specific growth rate. In phosphate-, nitrogen-, and carbon-limited chemostat cultures, in contrast, the transformation frequency depended on the specific growth rate; the transformation frequency equalled±10-4 at dilution rates close to µmax of 0.6h-1 and decreased to ±10-7 at a dilution rate of 0.1 h-1. We conclude that (1) DNA uptake for natural transformation in A. calcoaceticus does not serve a nutrient function and (2) competence induction is regulated via a promoter(s) that resembles the fis promoter from Escherichia coli.

A novel determinant (comA) essential for natural transformation competence in Neisseria gonorrhoeae and the effect of a comA defect on pilin variation.

A novel genetic determinant (comA) has been identified and found to be required for the transformation of piliated Neisseria gonorrhoeae. Mutants in comA of strain MS11 grow normally and are DNA-uptake proficient but blocked in the translocation of DNA into the cytoplasm. Here we show by site-specific mutagenesis and genetic complementation that only one of two open reading frames identified in comA is essential for competence: it encodes a protein (ComA) with a predicted size of 74 kDa. The comA gene maps upstream of the iga locus and is transcribed in the opposite orientation, probably under the control of a putative sigma 54-type promoter. While DNA probes specific for the N. gonorrhoeae iga locus reveal only a little cross-reactivity with commensal Neisseria species, the neighbouring comA gene appears to be present in most of them. ComA fusion proteins were obtained by in vitro translation. The synthesized gene products migrated atypically in SDS gels indicating its strong hydrophobicity. Several transmembrane alpha-helices were predicted from the amino acid sequence of ComA which, in the context of an observed sequence similarity with other inner membrane proteins, suggests a location for the protein in the inner membrane. Using piliated and non-piliated comA mutants the consequences of transformation deficiency on pilin phase variation were assessed. We show that the comA defect affects some but not all types of DNA rearrangements associated with pilE variation. The results are in agreement with previous observations supporting the notion that multiple recombination pathways contribute to the variability of pilE.

Physiological characterization of natural transformation in Acinetobacter calcoaceticus.

Acinetobacter calcoaceticus BD413 develops competence for natural transformation immediately after the start of the exponential growth-phase and remains competent up to e few hours into the stationary phase, after which competence gradually declines. The transformation frequencies obtained strongly depend on the kind of transforming DNA and the incubation time with DNA. Up to 25% of the cells in a culture can be transformed. DNA uptake in Acinetobacter does not display sequence specificity, is Mg(2+)-, Mn(2+)- or Ca(2+)-dependent and is uncoupler sensitive. The transforming DNA enters the cells in single-stranded form. These properties constitute a unique combination, not previously observed in other bacteria, and make A. caloaceticus ideally suited for detailed studies of the bioenergetics of DNA translocation.

Recovery of DNA from the Acinetobacter calcoaceticus chromosome by gap repair

A strain of Acinetobacter calcoaceticus that demonstrates unusually high competence for natural transformation by linear DNA has proven valuable for analysis of genes and gene clusters associated with aromatic catabolism. The transformation system allowed gap repair to be used to recover mutant chromosomal DNA within recombinant plasmids. The sizes of the recovered fragments, 5 and 7 kilobase pairs in length, indicate that gap repair will be a useful procedure for isolation of wild-type and modified gene clusters from the A. calcoaceticus chromosome.