Pharmacological YAP activation promotes regenerative repair of cutaneous wounds

Chronic cutaneous wounds remain a persistent unmet medical need that decreases life expectancy and quality of life. Here, we report that topical application of PY-60, a small-molecule activator of the transcriptional coactivator Yes-associated protein (YAP), promotes regenerative repair of cutaneous wounds in pig and human models. Pharmacological YAP activation enacts a reversible pro-proliferative transcriptional program in keratinocytes and dermal cells that results in accelerated re-epithelization and regranulation of the wound bed. These results demonstrate that transient topical administration of a YAP activating agent may represent a generalizable therapeutic approach to treating cutaneous wounds.

Progress toward a reduced phage genetic code

All known living organisms use at least 20 amino acids as the basic building blocks of life. Efforts to reduce the number of building blocks in a replicating system to below the 20 canonical amino acids have not been successful to date. In this work, we use filamentous phage as a model system to investigate the feasibility of removing methionine (Met) from the proteome. We show that all 24 elongation Met sites in the M13 phage genome can be replaced by other canonical amino acids. Most of these changes involve substitution of methionine by leucine (Leu), but in some cases additional compensatory mutations are required. Combining Met substituted sites in the proteome generally led to lower viability/infectivity of the mutant phages, which remains the major challenge in eliminating all methionines from the phage proteome. To date a total of 15 (out of all 24) elongation Mets have been simultaneously deleted from the M13 proteome, providing a useful foundation for future efforts to minimize the genetic code.

Small molecules that induce cardiomyogenesis in embryonic stem cells

A phenotypic cell-based screen of a large combinatorial chemical library led to the identification of a class of diaminopyrimidine compounds (cardiogenol A-D) which can selectively and efficiently induce mouse embryonic stem cells (ESCs) to differentiate into cardiomyocytes. ESC-derived cardiomyocytes were shown to express multiple cardiac muscle markers, including myosin heavy chain, GATA-4, MEF2, and Nkx2.5, and spontaneously form beating regions. Such small molecules will serve as useful chemical probes to study cardiac muscle differentiation and may ultimately facilitate the therapeutic application of ESCs for cardiac repair.

Development of a genetic selection for catalytic antibodies

The design and evaluation of a new genetic selection system for evolving catalytic antibodies with aldolase activity are described. Through a series of model selections, we have identified selection conditions where expression of a catalytically active antibody confers a growth advantage to Escherichia coli. In addition, we provide evidence that the growth advantage is a direct result of catalytic activity.

The generation of antibody combining sites containing catalytic residues

To expand the scope of antibody-catalysed reactions to those involving rate-limiting proton abstraction, such as elimination, isomerization and condensation reactions, we developed a new strategy--hapten charge complementarity. A hapten containing a benzyl ammonium group was used to elicit a specific base, a carboxylate, in the combining site of an antibody that catalysed a beta-elimination reaction. This was the first example of the use of a hapten to elicit a specific catalytic residue in an antibody combining site. A variety of kinetic and chemical modification experiments strongly suggest that a specific Asp or Glu residue in the combining site is responsible for catalysis. Preliminary results indicate that in addition to charge-charge complementarity, the nucleophilic reactivity of amino acid residues (Ser, Thr, Lys, Asp, Glu, Cys) in antibodies can be used as a selection tool. Antibodies were raised against a reactive epoxide group to elicit an antibody containing a uniquely reactive carboxylate or thiol group. Antibodies which bind the epoxide do catalyse a beta-elimination reaction, indicating the presence of a specific base in the combining site. Antibodies elicited to two closely related haptens do not catalyse the beta-elimination reaction.

Gene expression signatures and small-molecule compounds link a protein kinase to Plasmodium falciparum motility

Calcium-dependent protein kinases play a crucial role in intracellular calcium signaling in plants, some algae and protozoa. In Plasmodium falciparum, calcium-dependent protein kinase 1 (PfCDPK1) is expressed during schizogony in the erythrocytic stage as well as in the sporozoite stage. It is coexpressed with genes that encode the parasite motor complex, a cellular component required for parasite invasion of host cells, parasite motility and potentially cytokinesis. A targeted gene-disruption approach demonstrated that pfcdpk1 seems to be essential for parasite viability. An in vitro biochemical screen using recombinant PfCDPK1 against a library of 20,000 compounds resulted in the identification of a series of structurally related 2,6,9-trisubstituted purines. Compound treatment caused sudden developmental arrest at the late schizont stage in P. falciparum and a large reduction in intracellular parasites in Toxoplasma gondii, which suggests a possible role for PfCDPK1 in regulation of parasite motility during egress and invasion.

An Orthogonal T7 Replisome for Continuous Hypermutation and Accelerated Evolution in E. coli

Systems that perform continuous hypermutation of designated genes without compromising the integrity of the host genome can dramatically accelerate the evolution of new or enhanced protein functions. We describe an orthogonal DNA replication system in E. coli based on the controlled expression of the replisome of bacteriophage T7. The system replicates circular plasmids that enable high transformation efficiencies and seamless integration into standard molecular biology workflows. Engineering of T7 DNA polymerase yielded variant proteins with mutation rates of 1.7 × 10 -5 substitutions per base in vivo - 100,000-fold above the genomic mutation rate. Continuous evolution using the mutagenic T7 replisome was demonstrated by expanding the substrate scope of TEM-1 β-lactamase and increase activity 1,000-fold against clinically relevant monobactam and cephalosporin antibiotics in less than one week.