Comparative genomics of the niche-specific plant pathogen Streptomyces ipomoeae reveal novel genome content and organization.

IMPORTANCE: While most plant-pathogenic Streptomyces species cause scab disease on a variety of plant hosts, Streptomyces ipomoeae is the sole causative agent of soil rot disease of sweet potato and closely related plant species. Here, genome sequencing of virulent and avirulent S. ipomoeae strains coupled with comparative genomic analyses has identified genome content and organization features unique to this streptomycete plant pathogen. The results here will enable future research into the mechanisms used by S. ipomoeae to cause disease and to persist in its niche environment.

Artificial T Cell Mimetics to Combat Melanoma Tumor Growth.

Despite recent breakthroughs in melanoma treatment with anti-PD-1 immunotherapy, innovative approaches are needed to improve off-target effects. In this study, we report a T cell mimetic microparticle delivery of soluble PD1 aiming at providing a carrier substrate for future combinatorial and targeting efforts. Microparticles of sizes varying from (5 µm to-7 µm) were conjugated with soluble mouse or human PD-1 through nearly irreversible binding between streptavidin and biotin. PD-1 conjugated microparticles (PDMPs) suppressed 3-dimensional tumor growth of human A375 and mouse B16-F10 melanoma cells compared to control microparticles conjugated with the Fc portion of human IgG1 (IgG1MPs). This can be attributed to competitive inhibition by PDMPs on a melanoma cell-intrinsic PD-1/PD-L1 pathway. A single, local administration of mPDMPs in a B16-F10 mouse melanoma model inhibited tumor growth significantly compared to control IgMPs at the same dose. CD45+ immune cells were found to infiltrate tumors treated with mPDMPs as a mechanism for tumor control. These results collectively suggest that PDMPs can target the melanoma cell-intrinsic PD-1/PD-L1 pathway and that these artificial T cell mimetics can be the scaffold for further improvements in anti-tumor immunotherapy.

Long-adapter single-strand oligonucleotide probes for the massively multiplexed cloning of kilobase genome regions.

As the catalogue of sequenced genomes and metagenomes continues to grow, massively parallel approaches for the comprehensive and functional analysis of gene products and regulatory elements are becoming increasingly valuable. Current strategies to synthesize or clone complex libraries of DNA sequences are limited by the length of the DNA targets, throughput and cost. Here, we show that long-adapter single-strand oligonucleotide (LASSO) probes can capture and clone thousands of kilobase DNA fragments in a single reaction. As a proof-of-principle, we simultaneously cloned >3,000 bacterial open reading frames (ORFs) from E. coli genomic DNA (spanning 400-5,000 bp targets). Targets were enriched up to a median of ~60-fold compared to non-targeted genomic regions. At a cutoff of 3 times the median non-target reads per kilobase of genetic element per million reads, ~75% of the targeted ORFs were successfully captured. We also show that LASSO probes can clone human ORFs from complementary DNA, and an ORF library from a human-microbiome sample. LASSO probes could be used for the preparation of long-read sequencing libraries and for massively multiplexed cloning.

Affinity Purification of Proteins in Tag-Free Form: Split Intein-Mediated Ultrarapid Purification (SIRP).

Proteins purified using affinity-based chromatography often exploit a recombinant affinity tag. Existing methods for the removal of the extraneous tag, needed for many applications, suffer from poor efficiency and/or high cost. Here we describe a simple, efficient, and potentially low-cost approach-split intein-mediated ultrarapid purification (SIRP)-for both the purification of the desired tagged protein from Escherichia coli lysate and removal of the tag in less than 1 h. The N- and C-fragment of a self-cleaving variant of a naturally split DnaE intein from Nostoc punctiforme are genetically fused to the N-terminus of an affinity tag and a protein of interest (POI), respectively. The N-intein/affinity tag is used to functionalize an affinity resin. The high affinity between the N- and C-fragment of DnaE intein enables the POI to be purified from the lysate via affinity to the resin, and the intein-mediated C-terminal cleavage reaction causes tagless POI to be released into the flow-through. The intein cleavage reaction is strongly inhibited by divalent ions (e.g., Zn2+) under non-reducing conditions and is significantly enhanced by reducing conditions. The POI is cleaved efficiently regardless of the identity of the N-terminal amino acid except in the cases of threonine and proline, and the N-intein-functionalized affinity resin can be regenerated for multiple cycles of use.

Genome Content and Phylogenomics Reveal both Ancestral and Lateral Evolutionary Pathways in Plant-Pathogenic Streptomyces Species.

Streptomyces spp. are highly differentiated actinomycetes with large, linear chromosomes that encode an arsenal of biologically active molecules and catabolic enzymes. Members of this genus are well equipped for life in nutrient-limited environments and are common soil saprophytes. Out of the hundreds of species in the genus Streptomyces, a small group has evolved the ability to infect plants. The recent availability of Streptomyces genome sequences, including four genomes of pathogenic species, provided an opportunity to characterize the gene content specific to these pathogens and to study phylogenetic relationships among them. Genome sequencing, comparative genomics, and phylogenetic analysis enabled us to discriminate pathogenic from saprophytic Streptomyces strains; moreover, we calculated that the pathogen-specific genome contains 4,662 orthologs. Phylogenetic reconstruction suggested that Streptomyces scabies and S. ipomoeae share an ancestor but that their biosynthetic clusters encoding the required virulence factor thaxtomin have diverged. In contrast, S. turgidiscabies and S. acidiscabies, two relatively unrelated pathogens, possess highly similar thaxtomin biosynthesis clusters, which suggests that the acquisition of these genes was through lateral gene transfer.

A click chemistry approach to site-specific immobilization of a small laccase enables efficient direct electron transfer in a biocathode.

Controlled orientation of a small laccase on a multi-walled carbon nanotube electrode was achieved via copper-free click chemistry mediated immobilization. Modification of the enzyme was limited to only the tethering site and involved the genetic incorporation of the unnatural amino acid 4-azido-L-phenylalanine (AzF). This approach enabled efficient direct electron transfer.

Challenges and recent advances in affinity purification of tag-free proteins.

There is currently no generic, simple, lowcost method for affinity chromatographic purification of proteins in which the purified product is free of appended tags. Existing approaches for the purification of tagless proteins fall into two broad categories: (1) direct affinity-based capture of tag-free proteins that utilize affinity ligands specific to the target protein or class of target protein, and (2) removal of an appended affinity tag following tag-mediated protein capture. This paper reviews current state-of-the-art approaches for tagless protein purification in both categories, including specific examples of affinity ligands used for the capture of different classes of proteins and cleavage systems for affinity tag removal following chromatographic capture. A particular focus of this review is on recent developments in affinity tag removal systems utilizing split inteins.

Two-component protein hydrogels assembled using an engineered disulfide-forming protein-ligand pair.

We present the development of a two-component self-assembling protein hydrogel. The building blocks of the hydrogel are two liquid-phase protein block copolymers each containing (1) a subunit of the trimeric protein CutA as a cross-linker and (2) one member of a PDZ-domain-containing protein-ligand pair whose interaction was reinforced by an engineered disulfide linkage. Mixing of the two building blocks reconstitutes a self-assembling polypeptide unit, triggering hydrogel formation. This hydrogel exhibits extremely high solution stability at neutral and acidic pHs and in a wide range of temperatures (4-50 °C). Incorporation of a "docking station peptide" binding motif into a hydrogel building block enables functionalization of the hydrogel with target proteins tagged with a "docking protein". We demonstrated the application of an enzyme-functionalized hydrogel in a direct electron transfer enzymatic biocathode. These disulfide-reinforced protein hydrogels provide a potential new material for diverse applications including industrial biocatalysis, biosynthesis, biofuels, tissue engineering, and controlled drug delivery.

Split intein mediated ultra-rapid purification of tagless protein (SIRP).

Rapid and efficient tag removal remains a significant problem in recombinant protein purification. Using an engineered DnaE intein from Nostoc punctiforme, we developed a split intein mediated ultra-rapid purification (SIRP) method for the purification of tagless recombinant protein from E. coli lysate in less than 1 h. This system exhibits extraordinarily rapid thio-induced C-terminal cleavage with about 50% completion within 30 s at both 22°C and 6°C. This is the fastest C-terminal cleavage activity reported to date for inteins. Although the reaction kinetics slow down after the first minute, >90% cleavage completion is achieved within 30 min at 22°C, or within 3 h at 6°C. The ultra-rapid cleavage kinetics are made possible by the positioning of the purification tag at the split junction to the C-terminus of the intein N-fragment, thus avoiding potential steric hindrance of the critical interaction between the N- and C-extein. Target proteins are cleaved to >72% completion after 1 h of intein reaction regardless of the identity of the N-terminal amino acid except in the cases of threonine (50% cleavage) and proline. The C-terminal cleavage reaction can be effectively inhibited by divalent Zn(2+) under non-reducing conditions. Importantly, the association of the intein N- and C-fragments is reversible, enabling the column-bound intein N-fragment bait protein to be regenerated for multiple usages and further reducing the cost of protein purification. SIRP technology should provide a useful tool for the purification of tagless proteins and peptides.

Intein-triggered artificial protein hydrogels that support the immobilization of bioactive proteins.

Protein hydrogels have important applications in tissue engineering, drug delivery, and biofabrication. We present the development of a novel self-assembling protein hydrogel triggered by mixing two soluble protein block copolymers, each containing one half of a split intein. Mixing these building blocks initiates an intein trans-splicing reaction that yields a hydrogel that is highly stable over a wide range of pH (6-10) and temperature (4-50 °C), instantaneously recovers its mechanical properties after shear-induced breakdown, and is compatible with both aqueous and organic solvents. Incorporating a "docking station" peptide into the hydrogel building blocks enables simple and stable immobilization of docking protein-fused bioactive proteins in the hydrogel. This intein-triggered protein hydrogel technology opens new avenues for both in vitro metabolic pathway construction and functional/biocompatible tissue engineering scaffolds and provides a convenient platform for immobilizing enzymes in industrial biocatalysis.

Engineering split intein DnaE from Nostoc punctiforme for rapid protein purification.

We report the engineering of a DnaE intein able to catalyze rapid C-terminal cleavage in the absence of N-terminal cleavage. A single mutation in DnaE intein from Nostoc punctiforme PCC73102 (NpuDnaE), Asp118Gly, was introduced based on sequence alignment with a previously engineered C-terminal cleaving intein mini-MtuRecA. This mutation was able to both suppress N-terminal cleavage and significantly elevate C-terminal cleavage efficiency. Molecular modeling suggests that in NpuDnaE Asp118 forms a hydrogen bond with the penultimate Asn, preventing its spontaneous cyclization prior to N-terminal cleavage. Mutation of Asp118 to Gly essentially abolishes this restriction leading to subsequent C-terminal cleavage in the absence of N-terminal cleavage. The Gly118 NpuDnaE mutant exhibits rapid thio-dependent C-terminal cleavage kinetics with 80% completion within 3 h at room temperature. We used this newly engineered intein to develop both column-free and chromatography-based protein purification methods utilizing the elastin-like-polypeptide and chitin-binding protein as removable purification tags, respectively. We demonstrate rapid target protein purification to electrophoretic purity at yields up to 84 mg per liter of Escherichia coli culture.

Evidence that thaxtomin C is a pathogenicity determinant of Streptomyces ipomoeae, the causative agent of Streptomyces soil rot disease of sweet potato.

Streptomyces ipomoeae is the causal agent of Streptomyces soil rot of sweet potato, a disease marked by highly necrotic destruction of adventitious roots, including the development of necrotic lesions on the fleshy storage roots. Streptomyces potato scab pathogens produce a phytotoxin (thaxtomin A) that appears to facilitate their entrance into host plants. S. ipomoeae produces a less-modified thaxtomin derivative (thaxtomin C) whose role in pathogenicity has not been examined. Here, we cloned and sequenced the thaxtomin gene cluster (txt) of S. ipomoeae, and we then constructed targeted txt mutants that no longer produced thaxtomin C. The mutants were unable to penetrate intact adventitious roots but still caused necrosis on storage-root tissue. These results, taken in context with previous histopathological study of S. ipomoeae infection, suggest that thaxtomin C plays an essential role in inter- and intracellular penetration of adventitious sweet potato roots by S. ipomoeae. Once inside the plant host, the pathogen uses one or more yet-to-be-determined factors to necrotize root tissue, including that of any storage roots it encounters.