Nodulisporic acid E biosynthesis: characterisation of NodD1, an indole-diterpene prenyltransferase that acts on an emindole SB derived indole-diterpene scaffold.

Prenylation of aromatic compounds is a key tailoring reaction in biosynthesis of bioactive indole-diterpenes. Here, we identify NodD1 as the enzyme responsible for the bisprenylation of nodulisporic acid F. This prenyltransferase showed a preference for its natural indole-diterpene substrate whereas other related enzymes were not able to catalyse this conversion.

MIDAS: A Modular DNA Assembly System for Synthetic Biology.

A modular and hierarchical DNA assembly platform for synthetic biology based on Golden Gate (Type IIS restriction enzyme) cloning is described. This enabling technology, termed MIDAS (for Modular Idempotent DNA Assembly System), can be used to precisely assemble multiple DNA fragments in a single reaction using a standardized assembly design. It can be used to build genes from libraries of sequence-verified, reusable parts and to assemble multiple genes in a single vector, with full user control over gene order and orientation, as well as control of the direction of growth (polarity) of the multigene assembly, a feature that allows genes to be nested between other genes or genetic elements.

Draft Genome Sequence of the Filamentous Fungus ATCC 74245.

strain MF5954 (ATCC 74245) (formerly classified as sp.) is a filamentous fungal species known for its production of the secondary metabolite nodulisporic acid A. We present here the 41.

Heterologous Biosynthesis of Nodulisporic Acid F.

Nodulisporic acids comprise a group of valuable indole diterpenes that exhibit potent insecticidal activities. We report the identification of a gene cluster in the genome of the filamentous fungus Hypoxylon pulicicidum (Nodulisporium sp.) that contains genes responsible for the biosynthesis of nodulisporic acids.

Positron Emission Tomography Assessment of the Intranasal Delivery Route for Orexin A.

Intranasal drug delivery is a noninvasive drug delivery route that can enhance systemic delivery of therapeutics with poor oral bioavailability by exploiting the rich microvasculature within the nasal cavity. The intranasal delivery route has also been targeted as a method for improved brain uptake of neurotherapeutics, with a goal of harnessing putative, direct nose-to-brain pathways. Studies in rodents, nonhuman primates, and humans have pointed to the efficacy of intranasally delivered neurotherapeutics, while radiolabeling studies have analyzed brain uptake following intranasal administration.