Abstract: The present invention features improved processes and organisms for the production of methionine. The invention demonstrates that a ?metF organism or a ?metE AmetH organism, for example, mutants of C. glutamicum or E. coli, can use a methyl capped sulfide source, e.g., dimethyl disulfide (DMDS), as a source of both sulfur and a methyl group, bypassing the need for MetH/MetE and MetF activity and the need to reduce sulfate, for the synthesis of methionine. Also described in this patent are data implicating MetY (also called MetZ) as an enzyme that incorporates a methyl capped sulfide source, e.g., DMDS, into methionine. A ?metF ?metB strain of C. glutamicum can use a methyl capped sulfide source, e.g., DMDS, as a source of both sulfide and a methyl group. Furthermore, methionine production by engineered prototrophic organisms that overproduce O-acetyl-homoserine was improved by the addition of a methyl capped sulfide source, e.g., DMDS.

Abstract: This invention relates to methionine producing recombinant microorganisms. Specifically, this invention relates to recombinant strains of Corynebacterium that produce increased levels of methionine compared to their wild-type counterparts and further to methods of generating such microorganisms.

Abstract: The present invention features improved processes and organisms for the production of methionine. The invention demonstrates that a ?metF organism or a ?metE AmetH organism, for example, mutants of C. glutamicum or E. coli, can use a methyl capped sulfide source, e.g., dimethyl disulfide (DMDS), as a source of both sulfur and a methyl group, bypassing the need for MetH/MetE and MetF activity and the need to reduce sulfate, for the synthesis of methionine. Also described in this patent are data implicating MetY (also called MetZ) as an enzyme that incorporates a methyl capped sulfide source, e.g., DMDS, into methionine. A ?metF ?metB strain of C. glutamicum can use a methyl capped sulfide source, e.g., DMDS, as a source of both sulfide and a methyl group. Furthermore, methionine production by engineered prototrophic organisms that overproduce O-acetyl-homoserine was improved by the addition of a methyl capped sulfide source, e.g., DMDS.

Abstract: Nanostructures are made that include at least one species of assembly unit that is an antibody assembly unit in which at least one joining element, structural element or functional element is an antibody or antibody fragment. Antibody assembly units may have more than one antibody element. In addition, the antibody assembly units may contain non-antibody structural, functional or joining elements. The nanostructure is suitably prepared using a staged assembly method. In this method, a nanostructure intermediate having at least one unbound joining element is contacted with an assembly unit having a plurality of different joining elements. None of the joining elements of the assembly unit can interact with itself or with another joining element of the same assembly unit.

Abstract: The present invention provides methods and assembly units for the construction of nanostructures. Assembly of nanostructures proceeds by sequential, non-covalent, vectorial addition of an assembly unit to an initiator or nanostructure intermediate during an assembly cycle, a process termed “staged assembly.” Attachment of each assembly unit is mediated by specific, non-covalent binding of a single pre-determined joining element of one assembly unit to a complementary joining element on a target initiator or nanostructure intermediate. Each interaction of a joining element is designed such that the joining element does not interact with any other joining element of the assembly unit. Self-association of the assembly unit is therefore obviated: only one assembly unit can be added at a time to a target initiator or nanostructure intermediate.

Abstract: An elongate fastener that may not be removed without destruction is provided for insertion in adjacent cooperating holes defined in box structures and their closure elements to maintain closure. The fastener defines a head, larger than the hole to carry the fastener, that structurally carries a peripherally extending tab to aid manual manipulation. The head structurally connects an elongate perpendicularly extending body that fits in the cooperating holes and is formed by spaced peripheral webs that carry barb-like fasteners in their end portions distal from the head that allow insertion of the body through a hole by deformation, but thereafter expand responsive to retentent memory to prevent removal. The interconnection of the body and head is weaker in tensile strength than the material on either side of the interconnection so that the head may be removed from the body by manual manipulation of the peripheral tab, without the use of tools, to allow opening of the box structure.