Preface to the Princeton Landmarks in Biology Edition vii Preface xi Symbols Used xiii 1. The Importance of Islands 3 2. Area and Number of Speicies 8 3. Further Explanations of the Area-Diversity Pattern 19 4. The Strategy of Colonization 68 5. Invasibility and the Variable Niche 94 6. Stepping Stones and Biotic Exchange 123 7. Evolutionary Changes Following Colonization 145 8. Prospect 181 Glossary 185 References 193 Index 201

The Theory of Island Biogeography

Several microbes promote plant growth, and many microbial products that stimulate plant growth have been marketed. In this review we restrict ourselves to bacteria that are derived from and exert this effect on the root. Such bacteria are generally designated as PGPR (plant-growth-promoting rhizobacteria). The beneficial effects of these rhizobacteria on plant growth can be direct or indirect. This review begins with describing the conditions under which bacteria live in the rhizosphere. To exert their beneficial effects, bacteria usually must colonize the root surface efficiently. Therefore, bacterial traits required for root colonization are subsequently described. Finally, several mechanisms by which microbes can act beneficially on plant growth are described. Examples of direct plant growth promotion that are discussed include (a) biofertilization, (b) stimulation of root growth, (c) rhizoremediation, and (d) plant stress control. Mechanisms of biological control by which rhizobacteria can promote plant growth indirectly, i.e., by reducing the level of disease, include antibiosis, induction of systemic resistance, and competition for nutrients and niches.

Plant-growth-promoting rhizobacteria.

Plants host distinct bacterial communities on and inside various plant organs, of which those associated with roots and the leaf surface are best characterized. The phylogenetic composition of these communities is defined by relatively few bacterial phyla, including Actinobacteria, Bacteroidetes, Firmicutes, and Proteobacteria. A synthesis of available data suggests a two-step selection process by which the bacterial microbiota of roots is differentiated from the surrounding soil biome. Rhizodeposition appears to fuel an initial substrate-driven community shift in the rhizosphere, which converges with host genotype–dependent finetuning of microbiota profiles in the selection of root endophyte assemblages. Substrate-driven selection also underlies the establishment of phyllosphere communities but takes place solely at the immediate leaf surface. Both the leaf and root microbiota contain bacteria that provide indirect pathogen protection, but root microbiota members appear to serve additional host functions through the acquisition of nutrients from soil for plant growth. Thus, the plant microbiota emerges as a fundamental trait that includes mutualism enabled through diverse biochemical mechanisms, as revealed by studies on plant growth–promoting and plant health–promoting bacteria.

Structure and functions of the bacterial microbiota of plants

The above-ground parts of plants are normally colonized by a variety of bacteria, yeasts, and fungi. While a few microbial species can be isolated from within plant tissues, many more are recovered from the surfaces of healthy plants. The aerial habitat colonized by these microbes is termed the

Microbiology of the Phyllosphere

Microbial pathogenesis in cystic fibrosis: mucoid Pseudomonas aeruginosa and Burkholderia cepacia.

Activation of algD by AlgR is essential for mucoidy, a virulence factor expressed by Pseudomonas aeruginosa in cystic fibrosis. Two AlgR-binding sites, RB1 and RB2, located far upstream from the algD mRNA start site, are essential for the high-level activity of algD. However, the removal of RB1 and RB2 does not completely abolish inducibility of algD in response to environmental signals. In this work, a third binding site for AlgR, termed RB3, near the algD mRNA start site was characterized. Deletion of RB3 abrogated both the AlgR-binding ability and the residual inducibility of the algD promoter. DNase I footprinting analysis of RB3 resulted in a protection pattern spanning nucleotides -50 to -30. Eight of 10 residues encompassing a continuous region of protection within RB3 (positions -45 to -36) matched in the inverted orientation the conserved core sequence (ACCGTTCGTC) of RB1 and RB2. Quantitative binding measurements of AlgR association with RB1, RB2, and RB3 indicated that AlgR had significantly lower affinity for RB3 than for RB1 and RB2, with differences in the free energy of binding of 1.05 and 0.93 kcal/mol (4.39 and 3.89 kJ/mmol), respectively. Altering the core of RB2 to match the core of RB3 significantly reduced AlgR binding. Conversely, changing the core of RB3 to perfectly match the core of RB2 (mutant site termed RB3*) improved AlgR binding, approximating the affinity of RB2. RB3*, in the absence of the far upstream sites, showed an increase in activity, approaching the levels observed with the full-size algD promoter. Changing 4 nucleotides in two different combinations within the core of RB3 abolished the binding of AlgR to this site and resulted in a significant reduction of promoter activity in the presence of the far upstream sites. Thus, (i) the core sequence is essential for AlgR binding; (ii) the three binding sites, RB1, RB2, and RB3, are organized as an uneven palindrome with symmetrical sequences separated by 341 and 417 bp; and (iii) all three sites participate in algD activation.

AlgR-binding sites within the algD promoter make up a set of inverted repeats separated by a large intervening segment of DNA.

Plasmid pP51 of Pseudomonas sp. strain P51 contains two gene clusters encoding the degradation of chlorinated benzenes, tcbAB and tcbCDEF. A regulatory gene, tcbR, was located upstream and divergently transcribed from the chlorocatechol oxidative gene cluster tcbCDEF. The tcbR gene was characterized by DNA sequencing and expression studies with Escherichia coli and pET8c and appeared to encode a 32-kDa protein. The activity of the tcbR gene product was analyzed in Pseudomonas putida KT2442, in which it appeared to function as a positive regulator of tcbC expression. Protein extracts of both E. coli overproducing TcbR and Pseudomonas sp. strain P51 showed specific DNA binding to the 150-bp region that is located between the tcbR and tcbC genes. Primer extension mapping demonstrated that the transcription start sites of tcbR and tcbC are located in this region and that the divergent promoter sequences of both genes overlap. Amino acid sequence comparisons indicated that TcbR is a member of the LysR family of transcriptional activator proteins and shares a high degree of homology with other activator proteins involved in regulating the metabolism of aromatic compounds.

Characterization of the Pseudomonas sp. strain P51 gene tcbR, a LysR-type transcriptional activator of the tcbCDEF chlorocatechol oxidative operon, and analysis of the regulatory region.

A PCR-based toolbox for the culture-independent quantification of total bacterial abundances in plant environments

The tfdT gene is located upstream of and transcribed divergently from the tfdCDEF chlorocatechol-degradative operon on plasmid pJP4 of Ralstonia eutropha (formerly Alcaligenes eutrophus) JMP134. It is 684 bp long and encodes a 25-kDa protein. On the basis of its predicted amino acid sequence, the TfdT protein could be classified as a LysR-type transcriptional regulator. It has the highest degree of similarity with the proteins TcbR, ClcR, and TfdR, which are involved in the regulation of chloroaromatic breakdown. Despite this homology, the TfdT protein failed to activate the expression of its presumed target operon, tfdCDEF. This failure could be attributed to the inability of TfdT to bind the tfdC promoter region, an absolute requirement for transcriptional activation. Sequence analysis downstream of the tfdT gene revealed the presence of an insertion element-like element. We postulate that this element disrupted the tfdT open reading frame, leading to a premature termination and the production of a truncated, disfunctional TfdT protein. As an alternative to the inactivated TfdT protein, we propose that the product of the tfdR gene (or its identical twin, tfdS), located elsewhere on plasmid pJP4, can successfully take over the regulation of tfdCDEF expression. The TfdR protein was capable of binding to the tfdC promoter region and activated tfdCDEF gene expression by a factor of 80 to 100 when provided in cis as a tfdR-tfdCDEF hybrid regulon. Although to a lesser extent, induction of tfdCDEF expression was also observed when no functional TfdR protein was provided, implying cross-activation by chromosomally encoded regulatory elements in R. eutropha JMP134(pJP4).

The tfdR gene product can successfully take over the role of the insertion element-inactivated TfdT protein as a transcriptional activator of the tfdCDEF gene cluster, which encodes chlorocatechol degradation in Ralstonia eutropha JMP134(pJP4)

Johan H. J. Leveau

Papers

AlgR-binding sites within the algD promoter make up a set of inverted repeats separated by a large intervening segment of DNA.

Characterization of the Pseudomonas sp. strain P51 gene tcbR, a LysR-type transcriptional activator of the tcbCDEF chlorocatechol oxidative operon, and analysis of the regulatory region.

A PCR-based toolbox for the culture-independent quantification of total bacterial abundances in plant environments

The tfdR gene product can successfully take over the role of the insertion element-inactivated TfdT protein as a transcriptional activator of the tfdCDEF gene cluster, which encodes chlorocatechol degradation in Ralstonia eutropha JMP134(pJP4)

Microbial communities in the phyllosphere