The invention relates to PGT121-germline-targeting designs, trimer stabilization designs, combinations of those two, trimers designed with modified surfaces helpful for immunization regimens, other trimer modifications and on development of trimer nanoparticles and methods of making and using the same.

The present disclosure provides, inter alia, genetically encoded recombinant peptide biosensors comprising analyte-binding framework portions and signaling portions, wherein the signaling portions are present within the framework portions at sites or amino acid positions that undergo a conformational change upon interaction of the framework portion with an analyte.

The present invention relates to macromolecular complexes comprising micron-scale networks which include binding motifs thereon which allow the covalent bonding of the micron-scale networks to particles which provide nanoscale display surfaces. In particular the present invention relates to micron-scale networks of TMV coat proteins comprising a peptide tag (e.g. SpyTag) and particles providing a nanoscale display surface comprising GFP and a corresponding binding protein (e.g. SpyCatcher) wherein the peptide tag and binding protein pair are capable of spontaneously forming a covalent bond.

The present invention relates to variants of the general amyloid interaction motif (GAIM) of bacteriophage gene 3 protein (g3p) and fusion proteins thereof. The GAIM variants and fusion proteins of the invention are partially or fully deimmunized and demonstrate superior binding and specificity to a diverse array of amyloid proteins, and exhibit enhanced amyloid remodeling and inhibition of amyloid aggregation. The present invention further relates to nucleic acids, vectors, host cells, and methods of making the GAIM variants and fusion proteins thereof. The present invention also relates to pharmaceutical compositions and methods of increasing bacteriophage infectivity, methods of detecting amyloid aggregates, and methods of diagnosing and/or treating a disease associated with misfolded and/or aggregated amyloid protein.

The present disclosure relates generally to compositions and methods useful for the production of engineered antibodies having (i) multiple antigen-binding specificities and (ii) Fc regions that have been modified to promote heterodimer formation between heavy chains from antibodies with different specificities. Also provided are recombinant cells, recombinant nucleic acids encoding such engineered antibodies, as well as pharmaceutical compositions containing same.

The disclosure provides antigen binding domains that bind cluster of differentiation 3 (CD3) protein, comprising the antigen binding domains that bind CD3ε, polynucleotides encoding them, vectors, host cells, methods of making and using them.

The present disclosure discloses a method for expressing and preparing a bivalent bispecific antibody. In the present disclosure, each portion of a bivalent bispecific antibody and an immune hybrid protein thereof is respectively expressed in a suitable prokaryotic or eukaryotic cell system, separated and purified by high-performance affinity chromatography, and then spliced in vitro by trans-splicing reaction mediated by an intein, to prepare the bivalent specific antibody and an immune hybrid protein thereof.

Mussels strongly adhere to a variety of surfaces by secreting byssal threads that contain mussel foot proteins (Mfps). Recombinant production of Mfps presents an attractive route for preparing advanced adhesive materials. Using synthetic biology strategies, Mfp5 together with Mfp5 oligomers containing two or three consecutive, covalently-linked Mfp5 sequences (named Mfp5.sup.2 and Mfp5.sup.3) were synthesized. Positive correlations were found between Mfp5 molecular weight and underwater adhesive properties, including adhesion force, adhesion work, protein layer thickness, and recovery distance. Dopa-modified Mfp5.sup.3 displayed a high adhesion force (201±36 nN μm.sup.−1) and a high adhesion work (68±21 fJ μm.sup.−1) for 200 s cure times, higher than previously reported Mfp-mimetic adhesives. Results disclosed herein highlight the power of synthetic biology in producing biocompatible and highly adhesive Mfp-based materials.

The technology described herein is directed to regulated synthetic gene expression systems. In one aspect described herein are synthetic transcription factors (synTFs) comprising a DNA binding domain, a transcriptional effector domain, and a regulator protein. In other aspects described herein are gene expression systems comprising said synTFs and methods of treating diseases and disorders using said synTFs.

The disclosure provides compositions and methods for growing programmable enzyme-functionalized and sense-and-response bacterial cellulose living materials with engineered microbial co-cultures.