Mammalian expression cloning of nucleic acid binding proteins by agarose thin-layer gelshift clone selection

Here we report a functional screening technique to identify cDNAs encoding mammalian nucleic acid binding proteins. We have combined cDNA expression cloning with the agarose thin-layer gelshift assay technique to detect specific nucleic acid binding proteins from a mammalian expression library. We divided this cDNA expression library into multiple pools and transfected mammalian cells with the individual pools. Following transfection, we tested the expressed proteins for DNA-binding activity by agarose thin-layer electrophoretic gelshift assay. After we identified a single expression poolfor the presence of a DNA-binding protein, the corresponding cDNA pool was further divided into smaller aliquots. Then, the cDNA expression and gelshift clone selection was repeated until a single clone was isolated In contrast to traditional polyacrylamide gels, the agarose thin-layer is significantly faster and resolves larger DNA-protein complexes. This method can be widely used for the cDNA cloning of DNA- and RNA-binding proteins from various mammalian host cells.     

Semi-synthetic nucleic acid-protein conjugates: applications in life sciences and nanobiotechnology

Semi-synthetic conjugates of nucleic acids and proteins can be generated by either covalent coupling chemistry, or else by non-covalent biomolecular recognition systems, such as receptor-ligands of complementary nucleic acids. These nucleic acid-protein conjugates are versatile molecular tools which can be applied, for instance, in the self-assembly of high-affinity reagents for immunological detection assays, the fabrication of laterally microstructured biochips containing functional biological groups, and the biomimetic 'bottom-up' synthesis of nanostructured supramolecular devices. This review summarizes the current state-of-the-art synthesis and characterization methods of artificial nucleic acid-protein conjugates, as well as applications and perspectives for future developments of such hybrid biomolecular components in life sciences and nanobiotechnology.     

Three-dimensional structure of complexes of single-stranded DNA-binding proteins with DNA. IKe and fd gene 5 proteins form left-handed helices with single-stranded DNA

Specimen-tilting in an electron microscope was used to determine the three-dimensional architecture of the helical complexes formed with DNA by the closely related single-stranded DNA binding proteins of fd and IKe filamentous viruses. The fd gene 5 protein is the only member of the DNA-helix-destabilizing class of proteins whose structure has been determined crystallographically, and yet a parameter essential to molecular modeling of the co-operative interaction of this protein with DNA, the helix handedness, has not been available prior to this work. We find that complexes formed by titrating fd viral DNA with either the fd or IKe gene 5 protein have a left-handed helical sense. Complexes isolated from Escherichia coli infected by fd virus are also found to be left-handed helical; hence, the left-handed fd helices are not an artefact of reconstitution in vitro. Because the proteins and nucleic acid of the complexes are composed of asymmetric units which cannot be fitted equivalently to right-handed and left-handed helices, these results rule out a previous computer graphics atomic model for the helical fd complexes: a right-handed helix had been assumed for the model. Our work provides a defined three-dimensional structural framework within which to model the protein-DNA and protein-protein interactions of two structurally related proteins that bind contiguously and co-operatively on single-stranded DNAs.     

Localization of low-molecular-weight basic proteins in Bacillus megaterium spores by cross-linking with ultraviolet light.

Two low-molecular-weight basic proteins, termed A and B proteins, comprise about 15% of the protein of dormant spores of Bacillus megaterium. Irradiation of intact dormant spores with ultraviolet light results in covalent cross-linking of the A and B proteins to other spore macromolecules. The cross-linked A and B proteins are precipitated by ethanol and can be solubilized by treatment with deoxyribonuclease (75%) or ribonuclease (25%). Irradiation of complexes formed in vitro between deoxyribonucleic acid (DNA) or ribonucleic acid and a mixture of the low-molecular-weight basic proteins from spores also resulted in cross-linking of A and B proteins to nucleic acids. The dose-response curves for formation of covalent cross-links were similar for irradiation of both a protein-DNA complex in vitro and intact spores. However, if irradiation was carried out in vitro under conditions where DNA-protein complexes were disrupted, no covalent cross-links were formed. These data suggest that significant amounts of the low-molecular-weight basic proteins unique to bacterial spores are associated with spore DNA in vivo.     

Enabling high-throughput ligation-independent cloning and protein expression for the family of ubiquitin specific proteases

High-throughput methods to produce a large number of soluble recombinant protein variants are particularly important in the process of determining the three-dimensional structure of proteins and their complexes. Here, we describe a collection of protein expression vectors for ligation-independent cloning, which allow co-expression strategies by implementing different affinity tags and antibiotic resistances. Since the same PCR product can be inserted in all but one of the vectors, this allows efficiency in versatility while screening for optimal expression strategies. We first demonstrate the use of these vectors for protein expression in Escherichia coli, on a set of proteins belonging to the ubiquitin specific protease (USP) Family. We have selected 35 USPs, created 145 different expression constructs into the pETNKI-His-3C-LIC-kan vector, and obtained 38 soluble recombinant proteins for 21 different USPs. Finally, we exemplify the use of our vectors for bacterial co-expression and for expression in insect cells, with USP4 and USP7 respectively. We conclude that our ligation-independent cloning strategy allows for high-throughput screening for the expression of soluble proteins in a variety of vectors in E. coli and in insect cells. In addition, the same vectors can be used for co-expression studies, at least for simple binary complexes. Application in the family of ubiquitin specific proteases led to a number of soluble USPs that are used for functional and crystallization studies.     

A new analytical scale DNA affinity binding assay for analyses of specific protein-DNA interactions.

We describe a rapid analytical assay for identification of proteins binding to specific DNA sequences. The DAPSTER assay (DNA affinity preincubation specificity test of recognition assay) is a DNA affinity chromatography-based microassay that can discriminate between specific and nonspecific protein-DNA interactions. The assay is sensitive and can detect protein-DNA interactions and larger multicomponent complexes that can be missed by other analytical methods. Here we describe in detail the optimization and utilization of the DAPSTER assay to isolate AP-1 complexes and associated proteins in multimeric complexes bound to the AP-1 DNA element.     

Binding of the estradiol-receptor complex to reconstituted nucleoacidic protein from calf uterus

Non-histone protein-DNA complexes with acceptor activity for estradiol-receptor complexes were reconstituted from fractionated calf uterine chromatin. Acceptor activity had tissue specificity with target tissue binding exceeding non-target tissue binding. The binding of estradiol-receptor complexes to acceptor sites was dependent on intact non-histone protein-DNA complexes, reconstituted select non-histone proteins, and protein equivalent: DNA reconstitution ratios. [³H]Estradiol-receptor complexes were bound to reconstituted non-histone protein-DNA complexes (i.e., nucleoacidic protein) with a high affinity and with a limited number of binding sites. Fractionation of uterine chromatin non-histone proteins identified two major sets of non-histone proteins which had acceptor activity when reconstituted with DNA. Thus, it seems possible to reconstitute nucleoacidic protein fractions with specific acceptor activity for the calf uterine estrogen receptor.     

A new expression vector for high level protein production,one step purification and direct isotopic labeling of calmodulin-binding peptide fusion proteins

Calmodulin-binding peptide (CBP), a peptide of 26 amino acids derived from muscle myosin light chain kinase (MLCK), binds to calmodulin with nanomolar affinity. Proteins fused in frame with CBP can be purified from crude E. coli lysates in a single step using calmodulin affinity chromatography (Stofko-Hahn et al., 1992). Because the binding between CBP and calmodulin is calcium-dependent, the fusion protein can be eluted from the resin with virtually any buffer containing EGTA (2 mM) and used directly for many applications. To take full advantage of this affinity purification system, we constructed the versatile CBP fusion protein expression vector pCAL-n. The CBP coding sequence was positioned for fusion at the N-terminus, an advantage that ensures consistent high level synthesis of fusion proteins due to the efficient translation of the CBP in E. coli. The production of fusion proteins from pCAL-n is controlled by the tightly regulated T7lacO promoter. A versatile multiple cloning site (MCS) was included to facilitate the cloning of genes of interest. The protein coding sequence for the enzyme c-Jun N-terminal kinase (JNK) was inserted into the MCS of pCAL-n, and the resulting fusion protein CBP-JNK synthesized in E. coli cells at 15–20 mg/l culture. CBP-JNK was purified to near homogeneity in one step with calmodulin affinity resin. Purified CBP-JNK is fully active, and the CBP peptide tag can be removed by cleavage with thrombin. We also show that CBP can be efficiently phosphorylated by cAMP-dependent protein kinase. Hence, the purified fusion proteins can be labeled directly with [γ-³²P]ATP and used to probe protein–protein or protein–nucleic acid interactions.     

Footprinting protein-DNA complexes using the hydroxyl radical

Hydroxyl radical footprinting has been widely used for studying the structure of DNA and DNA-protein complexes. The high reactivity and lack of base specificity of the hydroxyl radical makes it an excellent probe for high-resolution footprinting of DNA-protein complexes; this technique can provide structural detail that is not achievable using DNase I footprinting. Hydroxyl radical footprinting experiments can be carried out using readily available and inexpensive reagents and lab equipment. This method involves using the hydroxyl radical to cleave a nucleic acid molecule that is bound to a protein, followed by separating the cleavage products on a denaturing electrophoresis gel to identify the protein-binding sites on the nucleic acid molecule. We describe a protocol for hydroxyl radical footprinting of DNA-protein complexes, along with a troubleshooting guide, that allows researchers to obtain efficient cleavage of DNA in the presence and absence of proteins. This protocol can be completed in 2 d.     

Proteins binding to site C2 (muE3) in the immunoglobulin heavy-chain enhancer exist in multiple oligomeric forms.

We describe the purification to near homogeneity of proteins binding to site C2 (muE3) in the immunoglobulin heavy-chain enhancer. Proteins binding to this site produce four protein-DNA complexes which are distinguished by their mobility in gel retardation assays and their elution properties in an anion exchange column. DNA affinity-purified preparations of three chromatographically separated pools, containing different subsets of the four complexes, each contained three polypeptides of 42.5, 44, and 45 kilodaltons (kDa). UV crosslinking of protein to enhancer DNA demonstrated that site C2-binding activities in the three different pools bound DNA through proteins of similar sizes (about 45 kDa), even though the protein-DNA complexes formed by these binding activities were quite distinct. Gel exclusion chromatography and equilibrium binding analyses indicated that the distinct protein-DNA complexes were due to different oligomeric forms of the individual subunits and that a larger multimeric form bound with high affinity to the heavy-chain enhancer site C2, while a smaller species had a much lower affinity for heavy-chain enhancer sequences. Purified protein has been used to map high-affinity binding sites for site C2-binding proteins within an immunoglobulin heavy-chain promoter and at site KE3 in the kappa light-chain enhancer.     

Ligation independent cloning vectors for expression of SUMO fusions

With demand increasing for the production of many different proteins for biophysical or biochemical analyses, rapid methods are needed for the cloning, expression and purification of native recombinant proteins. In particular, generic methods are required that are independent of the target gene sequence. To address this challenge we have constructed four Escherichia coli expression vectors that can be used for ligation independent cloning (LIC) of an amplified target gene sequence. These vectors represent the combinatorial pairing of two different parent vector backbones with two different affinity tags. The target gene is cloned downstream of the sequence coding for an affinity-tagged small ubiquitin related modifier (SUMO). Using enhanced green fluorescent protein (eGFP) as an example we demonstrate that the LIC procedure works with high efficiency for all four of the vectors. We also show that the resultant recombinant SUMO fusion proteins can be overexpressed in E. coli and readily isolated by standard affinity purification techniques. Importantly, the purified fusion product can be treated with recombinant SUMO hydrolase to yield a mature target protein with any residue except proline at the amino terminus. We demonstrate an application of this by generating recombinant eGFP containing a non-native amino terminal cysteine residue and using it as a substrate for expressed protein ligation (EPL). The reagents and techniques described here represent a generic method for the rapid cloning and production of a target protein, and would be appropriate for a high throughput genomic scale expression project.     

A simple physical model for the prediction and design of protein-DNA interactions

Protein-DNA interactions are crucial for many biological processes. Attempts to model these interactions have generally taken the form of amino acid-base recognition codes or purely sequence-based profile methods, which depend on the availability of extensive sequence and structural information for specific structural families, neglect side-chain conformational variability, and lack generality beyond the structural family used to train the model. Here, we take advantage of recent advances in rotamer-based protein design and the large number of structurally characterized protein-DNA complexes to develop and parameterize a simple physical model for protein-DNA interactions. The model shows considerable promise for redesigning amino acids at protein-DNA interfaces, as design calculations recover the amino acid residue identities and conformations at these interfaces with accuracies comparable to sequence recovery in globular proteins. The model shows promise also for predicting DNA-binding specificity for fixed protein sequences: native DNA sequences are selected correctly from pools of competing DNA substrates; however, incorporation of backbone movement will likely be required to improve performance in homology modeling applications. Interestingly, optimization of zinc finger protein amino acid sequences for high-affinity binding to specific DNA sequences results in proteins with little or no predicted specificity, suggesting that naturally occurring DNA-binding proteins are optimized for specificity rather than affinity. When combined with algorithms that optimize specificity directly, the simple computational model developed here should be useful for the engineering of proteins with novel DNA-binding specificities.     

Intermolecular and intramolecular readout mechanisms in protein-DNA recognition

Protein-DNA recognition plays an essential role in the regulation of gene expression. Regulatory proteins are known to recognize specific DNA sequences directly through atomic contacts (intermolecular readout) and/or indirectly through the conformational properties of the DNA (intramolecular readout). However, little is known about the respective contributions made by these so-called direct and indirect readout mechanisms. We addressed this question by making use of information extracted from a structural database containing many protein-DNA complexes. We quantified the specificity of intermolecular (direct) readout by statistical analysis of base-amino acid interactions within protein-DNA complexes. The specificity of the intramolecular (indirect) readout due to DNA was quantified by statistical analysis of the sequence-dependent DNA conformation. Systematic comparison of these specificities in a large number of protein-DNA complexes revealed that both intermolecular and intramolecular readouts contribute to the specificity of protein-DNA recognition, and that their relative contributions vary depending upon the protein-DNA complexes. We demonstrated that combination of the intermolecular and intramolecular energies derived from the statistical analyses lead to enhanced specificity, and that the combined energy could explain experimental data on binding affinity changes caused by base mutations. These results provided new insight into the relationship between specificity and structure in the process of protein-DNA recognition, which would lead to prediction of specific protein-DNA binding sites.     

Biomimetics: From Bioinformatics to Rational Design of Dendrimers as Gene Carriers

Biomimetics, or the use of principles of Nature for developing new materials, is a paradigm that could help Nanomedicine tremendously. One of the current challenges in Nanomedicine is the rational design of new efficient and safer gene carriers. Poly(amidoamine) (PAMAM) dendrimers are a well-known class of nanoparticles, extensively used as non-viral nucleic acid carriers, due to their positively charged end-groups. Yet, there are still several aspects that can be improved for their successful application in in vitro and in vivo systems, including their affinity for nucleic acids as well as lowering their cytotoxicity. In the search of new functional groups that could be used as new dendrimer-reactive groups, we followed a biomimetic approach to determine the amino acids with highest prevalence in protein-DNA interactions. Then we introduced them individually as terminal groups of dendrimers, generating a new class of nanoparticles. Molecular dynamics studies of two systems: PAMAM-Arg and PAMAM-Lys were also performed in order to describe the formation of complexes with DNA. Results confirmed that the introduction of amino acids as terminal groups in a dendrimer increases their affinity for DNA and the interactions in the complexes were characterized at atomic level. We end up by briefly discussing additional modifications that can be made to PAMAM dendrimers to turned them into promising new gene carriers.     

Insights into DNA solvation found in protein-DNA structures

The proteins that bind double-helical DNA present various microenvironments that sense and/or induce signals in the genetic material. The high-resolution structures of protein-DNA complexes reveal the nature of both the microenvironments and the conformational responses in DNA and protein. Complex networks of interactions within the structures somehow tie the protein and DNA together and induce the observed spatial forms. Here we show how the cumulative buildup of amino acid atoms around the sugars, phosphates, and bases in different protein-DNA complexes produces a binding cloud around the double helix and how different types of atoms fill that cloud. Rather than focusing on the principles of molecular binding and recognition suggested by the arrangements of amino acids and nucleotides in the macromolecular complexes, we consider the proteins in contact with DNA as organized solvents. We describe differences in the mix of atoms that come in closest contact with DNA, subtle sequence-dependent features in the microenvironment of the sugar-phosphate backbone, a direct link between the localized buildup of ionic species and the electrostatic potential surfaces of the DNA bases, and sites of atomic buildup above and below the basepair planes that transmit the unique features of the base environments along the chain backbone. The inferences about solvation that can be drawn from the survey provide new stimuli for improvement of nucleic acid force fields and fresh ideas for exploration of the properties of DNA in solution.     

Novel Function of the Fanconi Anemia Group J or RECQ1 Helicase to Disrupt Protein-DNA Complexes in a Replication Protein A-stimulated Manner

Understanding how cellular machinery deals with chromosomal genome complexity is an important question because protein bound to DNA may affect various cellular processes of nucleic acid metabolism. DNA helicases are at the forefront of such processes, yet there is only limited knowledge how they remodel protein-DNA complexes and how these mechanisms are regulated. We have determined that representative human RecQ and Fe-S cluster DNA helicases are potently blocked by a protein-DNA interaction. The Fanconi anemia group J (FANCJ) helicase partners with the single-stranded DNA-binding protein replication protein A (RPA) to displace BamHI-E111A bound to duplex DNA in a specific manner. Protein displacement was dependent on the ATPase-driven function of the helicase and unique properties of RPA. Further biochemical studies demonstrated that the shelterin proteins TRF1 and TRF2, which preferentially bind the telomeric repeat found at chromosome ends, effectively block FANCJ from unwinding the forked duplex telomeric substrate. RPA, but not the Escherichia coli single-stranded DNA-binding protein or shelterin factor Pot1, stimulated FANCJ ejection of TRF1 from the telomeric DNA substrate. FANCJ was also able to displace TRF2 from the telomeric substrate in an RPA-dependent manner. The stimulation of helicase-catalyzed protein displacement is also observed with the DNA helicase RECQ1, suggesting a conserved functional interaction of RPA-interacting helicases. These findings suggest that partnerships between RPA and interacting human DNA helicases may greatly enhance their ability to dislodge proteins bound to duplex DNA, an activity that is likely to be highly relevant to their biological roles in DNA metabolism.     

High level expression and single-step purification of hexahistidine-tagged L-2-hydroxyisocaproate dehydrogenase making use of a versatile expression vector set

Affinity tags as fusions to the N- or C-terminal part of proteins are valuable tools to facilitate the production and purification of proteins. In many cases, there may be the necessity to remove the tag after protein preparation to regain activity. Removal of the tag is accomplished by insertion of a unique amino acid sequence that is recognized and cleaved by a site specific protease. Here, we report the construction of an expression vector set that combines N- or C-terminal fusion to either a hexahistidine tag or Streptag with the possibility of tag removal by factor Xa or recombinant tobacco etch virus protease (rTEV), respectively. The vector set offers the option to produce different variants of the protein of interest by cloning the corresponding gene into four different Escherichia coli expression vectors. Either immobilized metal affinity chromatography or streptactin affinity chromatography can be used for the one-step purification. Furthermore, we show the successful application of the expression vector for C-terminal hexahistidine tagging. The expression and purification of His-tagged L-2-hydroxyisocaproate dehydrogenase yields fully active enzyme. The tag removal is here accomplished by a derivative of rTEV.