A cell surface display fluorescent biosensor for measuring MMP14 activity in real-time.

Despite numerous recent advances in imaging technologies, one continuing challenge for cell biologists and microscopists is the visualization and measurement of endogenous proteins as they function within living cells. Achieving this goal will provide a tool that investigators can use to associate cellular outcomes with the behavior and activity of many well-studied target proteins. Here, we describe the development of a plasmid-based fluorescent biosensor engineered to measure the location and activity of matrix metalloprotease-14 (MMP14).

Determining the subcellular location of new proteins from microscope images using local features.

Motivation: Evaluation of previous systems for automated determination of subcellular location from microscope images has been done using datasets in which each location class consisted of multiple images of the same representative protein. Here, we frame a more challenging and useful problem where previously unseen proteins are to be classified.

Results: Using CD-tagging, we generated two new image datasets for evaluation of this problem, which contain several different proteins for each location class.

Directed evolution of a fluorogen-activating single chain antibody for function and enhanced brightness in the cytoplasm.

Directed evolution is an exceptionally powerful tool that uses random mutant library generation and screening techniques to engineer or optimize functions of proteins. One class of proteins for which this process is particularly effective is antibodies, where properties such as antigen specificity and affinity can be selected to yield molecules with improved efficacy as molecular labels or in potential therapeutics. Typical antibody structure includes disulfide bonds that are required for stability and proper folding of the domains.

A variable light domain fluorogen activating protein homodimerizes to activate dimethylindole red.

Novel fluorescent tools such as green fluorescent protein analogues and fluorogen activating proteins (FAPs) are useful in biological imaging for tracking protein dynamics in real time with a low fluorescence background. FAPs are single-chain variable fragments (scFvs) selected from a yeast surface display library that produce fluorescence upon binding a specific dye or fluorogen that is normally not fluorescent when present in solution. FAPs generally consist of human immunoglobulin variable heavy (V(H)) and variable light (V(L)) domains covalently attached via a glycine- and serine-rich linker.

Blue fluorescent dye-protein complexes based on fluorogenic cyanine dyes and single chain antibody fragments.

Fluoromodules are complexes formed upon the noncovalent binding of a fluorogenic dye to its cognate biomolecular partner, which significantly enhances the fluorescence quantum yield of the dye. Previously, several single-chain, variable fragment (scFv) antibodies were selected from a yeast cell surface-displayed library that activated fluorescence from a family of unsymmetrical cyanine dyes covering much of the visible and near-IR spectrum. The current work expands our repertoire of genetically encodable scFv-dye pairs by selecting and characterizing a group of scFvs that activate fluorogenic violet-absorbing, blue-fluorescing cyanine dyes, based on oxazole and thiazole heterocycles.

Cell cycle dependence of protein subcellular location inferred from static, asynchronous images.

Protein subcellular location is one of the most important determinants of protein function during cellular processes. Changes in protein behavior during the cell cycle are expected to be involved in cellular reprogramming during disease and development, and there is therefore a critical need to understand cell-cycle dependent variation in protein localization which may be related to aberrant pathway activity. With this goal, it would be useful to have an automated method that can be applied on a proteomic scale to identify candidate proteins showing cell-cycle dependent variation of location.

Enhanced photostability of genetically encodable fluoromodules based on fluorogenic cyanine dyes and a promiscuous protein partner.

Fluoromodules are discrete complexes of biomolecules and fluorogenic dyes. Binding of the dyes to their cognate biomolecule partners results in enhanced dye fluorescence. We exploited a previously reported promiscuous binding interaction between a single-chain, variable fragment antibody protein and a family of cyanine dyes to create new protein-dye fluoromodules that exhibit enhanced photostability while retaining high affinity protein-dye binding.

scFv-based fluorogen activating proteins and variable domain inhibitors as fluorescent biosensor platforms.

Single chain antibodies (scFvs) are engineered proteins composed of IgG variable heavy (V(H)) and variable light (V(L)) domains tethered together by a flexible peptide linker. We have characterized the individual V(H) or V(L) domain activities of several scFvs isolated from a yeast surface-display library for their ability to bind environmentally sensitive fluorogenic dyes causing them to fluoresce. For many of the scFvs, both V(H) and V(L) domains are required for dye binding and fluorescence.

STED nanoscopy in living cells using Fluorogen Activating Proteins.

We demonstrate the effectiveness of a genetically encoded Malachite Green (MG) binding fluorogen activating protein (FAP) for live cell stimulated emission depletion nanoscopy (STED). Both extracellular and intracellular FAPs were tested in living cells using fluorogens with either membrane expressed FAP or as an intracellular FAP-actin fusion. Structures with FWHM of 110-122nm were observed.

A rainbow of fluoromodules: a promiscuous scFv protein binds to and activates a diverse set of fluorogenic cyanine dyes.

Combined magnetic and fluorescence cell sorting were used to select Fluorogen Activating Proteins (FAPs) from a yeast surface-displayed library for binding to the fluorogenic cyanine dye Dimethyl Indole Red (DIR). Several FAPs were selected that bind to the dye with low nanomolar Kd values and enhance fluorescence more than 100-fold. One of these FAPs also exhibits considerable promiscuity, binding with high affinity to several other fluorogenic cyanine dyes with emission wavelengths covering most of the visible and near-IR regions of the spectrum.

Fluorogen-activating single-chain antibodies for imaging cell surface proteins.

Imaging of live cells has been revolutionized by genetically encoded fluorescent probes, most famously green and other fluorescent proteins, but also peptide tags that bind exogenous fluorophores. We report here the development of protein reporters that generate fluorescence from otherwise dark molecules (fluorogens). Eight unique fluorogen activating proteins (FAPs) have been isolated by screening a library of human single-chain antibodies (scFvs) using derivatives of thiazole orange and malachite green.

The spectrum of Trp- mutants isolated as 5-fluoroanthranilate-resistant clones in Saccharomyces bayanus, S. mikatae and S. paradoxus.

5-Fluoroanthranilic acid (FAA)-resistant mutants were selected in homothallic diploids of three Saccharomyces species, taking care to isolate mutants of independent origin. Mutations were assigned to complementation groups by interspecific complementation with S. cerevisiae tester strains.

Large-scale automated analysis of location patterns in randomly tagged 3T3 cells.

Location proteomics is concerned with the systematic analysis of the subcellular location of proteins. In order to perform high-resolution, high-throughput analysis of all protein location patterns, automated methods are needed. Here we describe the use of such methods on a large collection of images obtained by automated microscopy to perform high-throughput analysis of endogenous proteins randomly-tagged with a fluorescent protein in NIH 3T3 cells.

Complete nucleotide sequence of a P2 family lysogenic bacteriophage, varphiMhaA1-PHL101, from Mannheimia haemolytica serotype A1.

The 34,525 nucleotide sequence of a double-stranded DNA bacteriophage (phiMhaA1-PHL101) from Mannheimia haemolytica serotype A1 has been determined. The phage encodes 50 open reading frames. Twenty-three of the proteins are similar to proteins of the P2 family of phages.

In vivo functional proteomics: mammalian genome annotation using CD-tagging.

A self-inactivating CD-tagging retroviral vector was used to introduce epitope and GFP tags into genes and proteins in NIH 3T3 cells. Several hundred cell clones, each expressing GFP fluorescence in a distinctive pattern, were isolated. Molecular analysis showed that a wide variety of genes and proteins, some known and some newly discovered, had been tagged.

Epitope tagging genomic DNA using a CD-tagging Tn10 minitransposon.

Here, we describe an efficient system for epitope tagging cloned genes by CD tagging using a mini-Tn10 transposon delivery vector. The system was tested against a lambdaFIX genomic clone of the human nucleolin gene. Transfection of HeLa cells with the tagged gene led to the expression of both the appropriately spliced tagged transcript and the appropriately localized tagged protein.

Intragenic suppression of a capsid assembly-defective P22 tailspike mutation.

The tailspike protein of bacteriophage P22 assembles with mature capsids during the final reaction in phage morphogenesis. The gene 9 mutation hmH3034 synthesizes a tailspike protein with a change at amino acid 100 from Asp to Asn. This mutant form of trimeric tailspike protein fails to assemble with capsids in vivo.

Characterization of bacteriophage P22 tailspike mutant proteins with altered endorhamnosidase and capsid assembly activities.

The tailspike protein of Salmonella typhimurium phage P22 is a multifunctional homotrimer which is involved in the terminal reaction of phage assembly, the adsorption of the phage to susceptible cells, and the hydrolysis of the Salmonella O-antigen during the first steps of phage infection. The proteins made from 15 mutant tailspike structural genes carried on high level expression plasmids have been analyzed with respect to their in vivo stability, quaternary structure, capsid assembly activity, and enzymatic activity. Nine mutants synthesize tailspike proteins which fail to accumulate to any appreciable level in vivo, and thus these proteins are probably degraded.

Using transposon Tn5 insertions to sequence bacteriophage T4 gene 11.

A simple and rapid method of creating an overlapping set of deletions in cloned DNA in preparation for sequencing has been developed. The method is based on a positive selection for Tn5 transposition into the cloned DNA fragment on a high-copy-number filamid, resolution of potential filamid dimers by filamentous phage infection, and the use of Tn5 both as a "portable" restriction enzyme site for in vitro DNA deletion and a "portable" sequencing primer binding site to initiate DNA sequencing reactions using a custom primer complementary to the outside ends of IS50. This new method has been utilized to sequence bacteriophage T4 gene 11, encoding the T4 baseplate protein gp11.

The isolation and sequence of missense and nonsense mutations in the cloned bacteriophage P22 tailspike protein gene.

Twenty-seven new mutations in the structural gene for the Salmonella typhimurium bacteriophage P22 tailspike protein have been isolated, mapped using a powerful plasmid-based genetic system and their DNA sequence changes determined. The mutations were generated by hydroxylamine treatment of the cloned gene on a plasmid expression vector. Assaying the activity of the tailspike protein produced from this plasmid and screening for plasmid mutants were accomplished by the in situ complementation of P22 capsids imbedded in soft agar to produce infectious phage.

Fine structure genetic and physical map of the phage P22 tail protein gene.

Bacteriophage P22 which are incapable of making functional tail protein can be propagated by the addition of purified mature tail protein trimers to either liquid or solidified medium. This unique in vitro complementation condition has allowed us to isolate 74 absolute lethal tail protein mutants of P22 after hydroxylamine mutagenesis. These phage mutants have an absolute requirement for purified P22 tail protein to be present in a soft agar overlay in order to form plaques and do not grow on any nonsense suppressing strains of Salmonella typhimurium.

Isolation of bacteriophage T4 baseplate proteins P7 and P8 and in vitro formation of the P10/P7/P8 assembly intermediate.

Two bacteriophage T4 proteins, P7 and P8, which are components of the phage baseplate have been purified to apparent homogeneity. P7 and P8 are the protein products of T4 genes 7 and 8. A plasmid has been constructed which contains approximately 5 kilobases of T4 DNA, including genes 7 and 8, under the control of the tac promoter.