Mechanism of the rhodium porphyrin-catalyzed cyclopropanation of alkenes.

The rhodium porphyrin-catalyzed cyclopropanation of alkenes by ethyl diazoacetate (EDA) is representative of a number of metal-mediated cyclopropanation reactions used widely in organic synthesis. The active intermediate in these reactions is thought to be a metal carbene complex, but evidence for the involvement of metal-olefin pi complexes has also been presented. Low-temperature infrared and nuclear magnetic resonance spectroscopies have been used to characterize a rhodium porphyrin-diazoalkyl adduct that results from the stoichiometric condensation of the catalyst and EDA. Optical spectroscopy suggests that this complex is the dominant steady-state species in the catalytic reaction. This compound decomposes thermally to provide cyclopropanes in the presence of styrene, suggesting that the carbene is indeed the active intermediate. Metal-alkene pi complexes have also been detected spectroscopically. Kinetic studies suggest that they mediate the rate of carbene formation from the diazoalkyl complex but are not attacked directly by EDA.

Mechanistic parallels between DNA replication, recombination and transcription.

The multiprotein complexes that mediate replication, transcription and homologous recombination in eukaryotic cells face many of the same molecular challenges. These include the recognition of DNA sites embedded in large chromatinized genomes, the denaturation of duplex DNA, and partial dissociation and reassociation at different stages of the catalytic cycle. Therefore, it is not surprising that several steps in the respective catalytic cycles are strikingly similar at the DNA level and may proceed by similar mechanisms. Some of these relationships are reviewed here. It is argued that speculation based on such 'crosspathway' comparisons may be a valuable paradigm for the design of new experiments.

Construction and evaluation of an automated light directed protein-detecting microarray synthesizer.

We have designed, constructed, and evaluated an automated instrument that has produced high-density arrays with more than 30 000 peptide features within a 1.5 cm(2) area of a glass slide surface. These arrays can be used for high throughput library screening for protein binding ligands, for potential drug candidate molecules, or for discovering biomarkers. The device consists of a novel fluidics system, a relay control electrical system, an optics system that implements Texas Instruments' digital micromirror device (DMD), and a microwave source for accelerated synthesis of peptide arrays. The instrument implements two novel solid phase chemical synthesis strategies for producing peptide and peptoid arrays. Biotin-streptavidin and DNP anti-DNP (dinitrophenol) models of antibody small molecule interactions were used to demonstrate and evaluate the instrument's capability to produce high-density protein detecting arrays. Several screening assay and detection schemes were explored with various levels of efficiency and assays with sensitivity of 10 nM were also possible.

Genetic selection of short peptides that support protein oligomerization in vivo.

An important goal in protein engineering is to control associations between designed proteins. This is most often done by fusing known, naturally occurring oligomerization modules, such as leucine zippers [1] [2] [3], to the proteins of interest [4] [5] [6]. It is of considerable interest to design or discover new oligomerization domains that have novel binding specificities [7] [8] [9] [10] [11] in order to expand the 'toolbox' of the protein engineer and also to eliminate associations of the designed proteins with endogenous factors. We report here a simple genetic selection scheme through which to search libraries for peptides that are able to mediate homodimerization or higher-order self-oligomerization of a protein in vivo. We found several peptides that support oligomerization of the lambda repressor DNA-binding domain in Escherichia coli cells, some of them as efficiently as the endogenous dimerization domain or the GCN4 leucine zipper. Many are very small, comprising as few as six residues. This study strongly supports the notion that peptide sequence space is rich in small peptides, which might be useful in protein engineering and other applications.

Evidence for two modes of cooperative DNA binding in vivo that do not involve direct protein-protein interactions.

BACKGROUND: The promoter regions of most eukaryotic genes contain binding sites for more than one transcriptional activator and these activators often bind cooperatively to promoters. The most common type of cooperativity is supported by direct protein-protein interactions. Recent studies have shown that proteins that do not specifically interact with one another can bind cooperatively to chromatin in vitro. probably by the localized destabilization of nucleosome structure by one factor, facilitating binding of another to a nearby site. This mechanism does not require that the transcription factors have activation domains. We have examined whether this phenomenon occurs in vivo. RESULTS: Unrelated non-interacting proteins can bind DNA cooperatively in yeast cells; this cooperative binding can contribute significantly to transcriptional activation, does not require that both factors have activation domains and is only operative over relatively short distances. In addition to this 'short-range' mechanism, unrelated non-interacting proteins can bind cooperatively to sites separated by hundreds of base pairs, so long as both have potent activation domains. CONCLUSION: Cooperative binding of transcription factors in vivo can occur by several mechanisms, some of which do not require direct protein-protein interactions and which cannot be detected in vitro using naked DNA templates. These findings must be taken into account when evaluating mechanisms for synergistic transcriptional activation.

Selection and application of peptide-binding peptides.

Peptide-binding ligands would be useful for directing reagents to particular epitopes in a protein, the detection of peptide hormones, and many other applications. Here we show that peptides of modest size isolated from a library using a simple genetic assay can act as specific receptors for other peptides. The equilibrium dissociation constants of these peptide-peptide complexes are higher than those of typical monoclonal antibody-epitope complexes. Nonetheless, as shown here, these peptide-binding peptides can be used to detect or purify proteins containing the partner peptide.

DMC1 functions in a Saccharomyces cerevisiae meiotic pathway that is largely independent of the RAD51 pathway.

Meiotic recombination in the yeast Saccharomyces cerevisiae requires two similar recA-like proteins, Dmc1p and Rad51p. A screen for dominant meiotic mutants provided DMC1-G126D, a dominant allele mutated in the conserved ATP-binding site (specifically, the A-loop motif) that confers a null phenotype. A recessive null allele, dmc1-K69E, was isolated as an intragenic suppressor of DMC1-G126D. Dmc1-K69Ep, unlike Dmc1p, does not interact homotypically in a two-hybrid assay, although it does interact with other fusion proteins identified by two-hybrid screen with Dmc1p. Dmc1p, unlike Rad51p, does not interact in the two-hybrid assay with Rad52p or Rad54p. However, Dmc1p does interact with Tid1p, a Rad54p homologue, with Tid4p, a Rad16p homologue, and with other fusion proteins that do not interact with Rad51p, suggesting that Dmc1p and Rad51p function in separate, though possibly overlapping, recombinational repair complexes. Epistasis analysis suggests that DMC1 and RAD51 function in separate pathways responsible for meiotic recombination. Taken together, our results are consistent with a requirement for DMC1 for meiosis-specific entry of DNA double-strand break ends into chromatin. Interestingly, the pattern on CHEF gels of chromosome fragments that result from meiotic DNA double-strand break formation is different in DMC1 mutant strains from that seen in rad50S strains.

Protein microarrays: prospects and problems.

Protein microarrays are potentially powerful tools in biochemistry and molecular biology. Two types of protein microarrays are defined. One, termed a protein function array, will consist of thousands of native proteins immobilized in a defined pattern. Such arrays can be utilized for massively parallel testing of protein function, hence the name. The other type is termed a protein-detecting array. This will consist of large numbers of arrayed protein-binding agents. These arrays will allow for expression profiling to be done at the protein level. In this article, some of the major technological challenges to the development of protein arrays are discussed, along with potential solutions.

From carpet bombing to cruise missiles: the 'second-order' mechanisms used by transcription factors to ensure specific DNA binding in vivo.

Transcription factors generally have only modest specificity for their target sites, yet must find them in a sea of non-specific DNA. Some transcription factors are expressed at very high levels, to ensure that, despite losses to non-specific binding, the promoter is still occupied (the carpet-bombing strategy). Others increase their binding specificity by collaborating with other factors in a variety of ways.

Small-molecule-based strategies for controlling gene expression.

A central goal in chemical biology is to gain control over biological pathways using small molecules, and the mRNA-synthesizing machinery is a particular important target. New advances in our understanding of transcriptional regulation suggests strategies to manipulate these pathways using small molecules.

An inhibitor of sequence-specific proteolysis that targets the substrate rather than the enzyme.

BACKGROUND: Traditional protease inhibitors target the active site of the enzyme. However, since most proteases act on multiple substrates, even the most specific protease inhibitors will affect the levels of a number of different proteins. However, if substrate-targeted inhibitors could be developed, much higher levels of specificity could be achieved. In theory, compounds that bind the cleavage site of a particular substrate could block its interaction with a protease without having any effect on the processing of other substrates of that protease. RESULTS: A model system is presented that demonstrates the feasibility of substrate-targeted inhibition of proteolysis. A peptide selected genetically to bind a 14-residue epitope that encompasses the cleavage site of human pro-IL-1beta was shown to inhibit interleukin-converting enzyme (ICE)-mediated proteolysis of model substrates containing the 14-mer target sequence. However, the peptide had no effect on the cleavage of other ICE substrates with different amino acids flanking the minimal cleavage site. CONCLUSIONS: This study demonstrates the feasibility of substrate-targeted inhibition of proteolysis. More potent compounds must be developed before substrate-targeted inhibitors can be used routinely. Nonetheless, this novel strategy for protease inhibition seems promising for the development of extremely selective molecules with which to manipulate the maturation of many important pro-hormones, -cytokines and -proteins.

The dangers of 'splicing and dicing': on the use of chimeric transcriptional activators in vitro.

Chimeric transcription factors composed of heterologous DNA-binding and activation domains are often used to study the regulation of gene expression. The fact that such preparations also contain molecules in which only one of the two domains is functional is often overlooked, but a surprisingly small proportion of inactive domains could cause serious problems in the interpretation of quantitative data.

New chemistry for the study of multiprotein complexes: the six-histidine tag as a receptor for a protein crosslinking reagent.

BACKGROUND: To study very large macromolecular complexes, it would be useful to be able to incorporate probe molecules, such as fluorescent tags or photoactivatable crosslinkers, into specific sites on proteins. Current methods for doing this use relatively large amounts of highly purified protein, limiting the general utility of these approaches. The need for covalent posttranslational chemistry also makes it extremely difficult to use modified proteins in studies of native complexes in crude lysates or in living cells. We set out to develop a protein tag that would circumvent these problems. RESULTS: A very simple type of molecular recognition, metal-ligand complexation, can be used to deliver a nickel-based crosslinking reagent to proteins containing a six-histidine (His6) tag. When activated with a peracid, the His6-Ni complex mediates oxidative crosslinking of nearby proteins. The crosslinking reaction does not involve freely diffusible intermediates, and thus only those proteins in close proximity to the His6-tagged polypeptide are crosslinked. CONCLUSIONS: The His6 tag, commonly used as an affinity handle for the purification of recombinant proteins, can also be used as an internal receptor for an oxidative protein-crosslinking reagent. No covalent protein modifications are necessary, since the His6 tag is introduced at the DNA level. The crosslinking reaction is fast, efficient in most cases, and provides products that are easily separated from most other proteins present. This methodology should find widespread use in the study of multiprotein complexes.

Scope, limitations and mechanistic aspects of the photo-induced cross-linking of proteins by water-soluble metal complexes.

BACKGROUND: Chemical cross-linking is a valuable tool with which to study protein-protein interactions. Recently, a new kind of cross-linking reaction was developed in which the photolysis of associated proteins with visible light in the presence of ammonium persulfate and tris(2,2'-bipyridyl)ruthenium(II) dication or palladium(II) porphyrins results in rapid and efficient covalent coupling (Fancy, D.A. & Kodadek, T. (1999). Proc. Natl. Acad. Sci. USA 96, 6020-6024 and Kim, K., Fancy, D.A. & Kodadek, T. (1999). J. Am. Chem. Soc. 121, 11896-11897). Here, mechanistic and practical aspects of the reaction of importance for its application to biochemical problems are examined. RESULTS: It is shown that the photo-initiated cross-linking chemistry can be optimized for the analysis of protein-protein interactions in crude cell extracts. A number of commonly used epitope or affinity tags survive the reaction in functional form, allowing the simple visualization of the cross-linked products, or their isolation. It is shown that very little light-independent oxidation of protein residues occurs and that significant perturbation of complexes of interest prior to the brief photolysis period does not occur. Finally, evidence is presented that is consistent with a mechanistic model in which ammonium persulfate functions simply as an electron acceptor, facilitating the generation of the key high valent metal complex from the photoexcited species by electron transfer. In the absence of an electron acceptor, a much lower efficiency reaction is observed that appears to involve products resulting from reaction of the excited state metal complex with molecular oxygen. CONCLUSIONS: These results provide useful practical information for chemists and biochemists who may wish to employ this new cross-linking chemistry for the analysis of protein complexes. They also shed new light on the mechanism of this interesting reaction.

Photo-induced oxidative cross-linking as a method to evaluate the specificity of protein-ligand interactions.

The isolation of protein-binding synthetic molecules from combinatorial libraries or compound collections is now a common practice in chemical biology. An important, but underdeveloped, aspect of characterizing the binding properties of such molecules is their level of binding specificity. This is often evaluated by simply measuring the equilibrium binding affinity of the compound of interest with its target protein and comparing this value with its affinity to one or a few other purified proteins selected at random. These measurements may not reflect accurately the ability of the compound to seek out its target in a complex mixture of proteins such as a cell extract or serum. A more desirable alternative would be to develop solution assays that measure directly the binding of the molecule of interest to both target and competitor proteins in complex solutions. In this report, we evaluate a rapid and efficient photo-triggered cross-linking reaction for assessing binding specificity of synthetic molecules in protein mixtures. Using peptide-protein complexes, we demonstrate that this reaction provides an unbiased view of the peptide-protein contacts present in solution under a given set of conditions and thus is useful for assessing binding specificity. We also discuss the potential application of this chemistry to the related, but more difficult, problem of the identification of protein targets of bioactive molecules.

Functional interactions between phage T4 and E. coli DNA-binding proteins during the presynapsis phase of homologous recombination.

The "protein machine" for phage T4 homologous recombination has begun to be assembled in vitro. A particularly heavily studied reaction has been the uvsX protein (a RecA-like strand transferase)-mediated homologous pairing reaction between single and double-stranded DNAs, a key step in the recombination cycle in vivo. A necessary prerequisite for uvsX protein-mediated pairing is the polymerization of this factor along the invading single strand, a process known as presynapsis. Recent work has indicated that at least two other T4 recombination factors are involved in this process as well, the uvsY and gene 32 products. These proteins are also ssDNA-binding factors and exhibit an affinity for UvsX and each other. In order to begin to sort out the potential functional roles played by these protein-protein interactions in presynapsis, I have examined the ability of the uvsX protein to form stable filaments along ssDNA in the presence of these proteins. It is shown that the uvsY protein relieves the inhibition to filament formation due to the presence of the gene 32 protein, but experiments with the E. coli SSB protein (the bacterial analogue of gp32) suggest that this effect does not involve a direct interaction between UvsY and gp32.

The role of the bacteriophage T4 gene 32 protein in homologous pairing.

The gene 32 protein of the bacteriophage T4 is required for efficient genetic recombination in infected Eschericia coli cells and strongly stimulates in vitro pairing catalyzed by the phage uvsX protein, a RecA-like strand transferase. This helix-destabilizing factor is known to bind tightly and cooperatively to single-stranded DNA and to interact specifically with the uvsX protein as well as other phage gene products. However, its detailed role in homologous pairing is not well understood. I show here that when the efficiency of uvsX protein-mediated pairing is examined at different gene 32 protein and duplex DNA concentrations, a correlation between the two is found, suggesting that the two interact in a functionally important manner during the reaction. These and other data are consistent with a model in which the gene 32 protein binds to the strand displaced from the recipient duplex during pairing, thereby stabilizing the heteroduplex product. An alternative model in which the gene 32 protein replaces UvsX on the invading strand, thereby freeing the strand transferase to bind to the displaced strand, is also considered.

Inhibition of protein-mediated homologous pairing by a DNA helicase.

Protein-mediated exchange of homologous DNA strands is a central reaction in general genetic recombination and the mechanism by which proteins mediate this process in vivo is a topic of keen interest. The dda protein of the bacteriophage T4 is a DNA helicase that has been shown to accelerate branch migration catalyzed by the phage uvsX and gene 32 proteins in vitro (Kodadek, T., and Alberts, B.M. (1987) Nature 326, 312-314). This study did not address the potential role of the helicase in protein-mediated homologous pairing, the first phase of the overall strand-exchange reaction. It is shown here that the dda protein inhibits uvsX protein-mediated pairing between homologous single and double-stranded DNAs. Experiments using deproteinized heteroduplex joints demonstrate that the dda helicase is capable of unwinding these structures to some extent and suggests that this activity may be responsible for the observed inhibition of pairing. It is found that the helicase also reduces the level of uvsX protein-mediated, single-stranded DNA-dependent ATP hydrolysis in the strand-exchange reactions, suggesting that the helicase may also act to destabilize the uvsX protein-DNA filaments that are important intermediates in the pairing reaction. Three other helicases are found to have no effect on the uvsX protein-mediated pairing reaction. A model rationalizing the ability of the dda protein to both inhibit homologous pairing and stimulate branch migration is presented and possible in vivo roles for this interesting activity are discussed.

How does the GAL4 transcription factor recognize the appropriate DNA binding sites in vivo?

The GAL4 protein of yeast activates the transcription of several genes involved in galactose metabolism. This event requires that GAL4 bind to upstream activation sites with the consensus sequence 5'-CGGN5(T/A)N5CCG-3'. We review the general requirements that must be met for a protein such as GAL4 to find and remain bound to its target site in vivo. Evidence is presented that the GAL4 DNA-binding domain itself has insufficient intrinsic sequence selectivity to fulfill the task of targeting GAL4 to the appropriate sites in a yeast genome. Possible mechanisms by which this selectivity is enhanced in vivo are discussed.