Ian A. MacNeil

Cloning the Soil Metagenome: a Strategy for Accessing the Genetic and Functional Diversity of Uncultured Microorganisms

ABSTRACT Recent progress in molecular microbial ecology has revealed that traditional culturing methods fail to represent the scope of microbial diversity in nature, since only a small proportion of viable microorganisms in a sample are recovered by culturing techniques. To develop methods to investigate the full extent of microbial diversity, we used a bacterial artificial chromosome (BAC) vector to construct libraries of genomic DNA isolated directly from soil (termed metagenomic libraries). To date, we have constructed two such libraries, which contain more than 1 Gbp of DNA. Phylogenetic analysis of 16S rRNA gene sequences recovered from one of the libraries indicates that the BAC libraries contain DNA from a wide diversity of microbial phyla, including sequences from diverse taxa such as the low-G+C, gram-positive Acidobacterium,Cytophagales, and Proteobacteria. Initial screening of the libraries in Escherichia coli identified several clones that express heterologous genes from the inserts, confirming that the BAC vector can be used to maintain, express, and analyze environmental DNA. The phenotypes expressed by these clones include antibacterial, lipase, amylase, nuclease, and hemolytic activities. Metagenomic libraries are a powerful tool for exploring soil microbial diversity, providing access to the genetic information of uncultured soil microorganisms. Such libraries will be the basis of new initiatives to conduct genomic studies that link phylogenetic and functional information about the microbiota of environments dominated by microorganisms that are refractory to cultivation.

Genetically Modified Bacterial Strains and Novel Bacterial Artificial Chromosome Shuttle Vectors for Constructing Environmental Libraries and Detecting Heterologous Natural Products in Multiple Expression Hosts

ABSTRACT The enormous diversity of uncultured microorganisms in soil and other environments provides a potentially rich source of novel natural products, which is critically important for drug discovery efforts. Our investigators reported previously on the creation and screening of an Escherichia coli library containing soil DNA cloned and expressed in a bacterial artificial chromosome (BAC) vector. In that initial study, our group identified novel enzyme activities and a family of antibacterial small molecules encoded by soil DNA cloned and expressed in E. coli. To continue our pilot study of the utility and feasibility of this approach to natural product drug discovery, we have expanded our technology to include Streptomyces lividans and Pseudomonas putida as additional hosts with different expression capabilities, and herein we describe the tools we developed for transferring environmental libraries into all three expression hosts and screening for novel activities. These tools include derivatives of S. lividans that contain complete and unmarked deletions of the act and red endogenous pigment gene clusters, a derivative of P. putida that can accept environmental DNA vectors and integrate the heterologous DNA into the chromosome, and new BAC shuttle vectors for transferring large fragments of environmental DNA from E. coli to both S. lividans and P. putida by high-throughput conjugation. Finally, we used these tools to confirm that the three hosts have different expression capabilities for some known gene clusters.

Structural basis of Src tyrosine kinase inhibition with a new class of potent and selective trisubstituted purine-based compounds.

The tyrosine kinase pp60src (Src) is the prototypical member of a family of proteins that participate in a broad array of cellular signal transduction processes, including cell growth, differentiation, survival, adhesion, and migration. Abnormal Src family kinase (SFK) signaling has been linked to several disease states, including osteoporosis and cancer metastases. Src has thus emerged as a molecular target for the discovery of small‐molecule inhibitors that regulate Src kinase activity by binding to the ATP pocket within the catalytic domain. Here, we present crystal structures of the kinase domain of Src in complex with two purine‐based inhibitors: AP23451, a small‐molecule inhibitor designed to inhibit Src‐dependent bone resorption, and AP23464, a small‐molecule inhibitor designed to inhibit the Src‐dependent metastatic spread of cancer. In each case, a trisubstituted purine template core was elaborated using structure‐based drug design to yield a potent Src kinase inhibitor. These structures represent early examples of high affinity purine‐based Src family kinase–inhibitor complexes, and they provide a detailed view of the specific protein–ligand interactions that lead to potent inhibition of Src. In particular, the 3‐hydroxyphenethyl N9 substituent of AP23464 forms unique interactions with the protein that are critical to the picomolar affinity of this compound for Src. The comparison of these new structures with two relevant kinase–inhibitor complexes provides a structural basis for the observed kinase inhibitory selectivity. Further comparisons reveal a concerted induced‐fit movement between the N‐ and C‐terminal lobes of the kinase that correlates with the affinity of the ligand. Binding of the most potent inhibitor, AP23464, results in the largest induced‐fit movement, which can be directly linked to interactions of the hydrophenethyl N9 substituent with a region at the interface between the two lobes. A less pronounced induced‐fit movement is also observed in the Src–AP23451 complex. These new structures illustrate how the combination of structural, computational, and medicinal chemistry can be used to rationalize the process of developing high affinity, selective tyrosine kinase inhibitors as potential therapeutic agents.

Structure-activity relationships of a novel class of SRC SH2 inhibitors

The structure-activity relationships (SAR) of a novel class of Src SH2 inhibitors are described. Variation at the pY+1 and pY+3 side chain positions using 2,4- and 2,5-substituted thiazoles and 1,2,4-oxadiazoles as scaffolds resulted in inhibitors that bound as well as the standard tetrapeptide Ac-pYEEI-NH2.

Accessing the Genomes of Uncultivated Microbes for Novel Natural Products

Recent findings suggest that only 1% or less of the total number of soil microbial species can be easily cultivated. The fact that uncultured species represent spectacular microbial diversity has sparked great interest in these microorganisms as a potentially prolific source of untapped genetic diversity encoding novel natural products. Multiple approaches are being developed to access this diversity, such as methods to improve the ability to cultivate some of these organisms, most of which are not easily grown under standard laboratory conditions. Here we discuss an alternative approach, aimed at developing technologies for gaining access to the genomes of uncultivated microbes by creating environmental DNA libraries. This method involves isolating large DNA fragments (100–300 kb) from soil microorganisms (or from microorganisms derived from other environments), and inserting these fragments into a bacterial vector, thus generating recombinant DNA libraries. Such libraries are then used to identify novel natural products by various means, including expression of the DNA in a heterologous host strain and screening for activities, or by directly analyzing the DNA for genes of interest. The recombinant approach thus obviates the need for culturing diverse microorganisms and provides a relatively unbiased sampling of the vast untapped genetic diversity present in various microenvironments. As an additional advantage, the genes encoding a product of interest are already isolated and can be analyzed using the tools of bioinformatics, thus providing a potential boost to the efforts of analytical chemists to identify the product. Furthermore, the possibility of regulating the expression of isolated environmental gene clusters or combining them with genes for other pathways to obtain new compounds could furnish a further advantage over traditional naturalproduct discovery methodologies.