Engineered Chimeras Unveil Swappable Modular Features of Fatty Acid and Polyketide Synthase Acyl Carrier Proteins.

The strategic redesign of microbial biosynthetic pathways is a compelling route to access molecules of diverse structure and function in a potentially environmentally sustainable fashion. The promise of this approach hinges on an improved understanding of acyl carrier proteins (ACPs), which serve as central hubs in biosynthetic pathways. These small, flexible proteins mediate the transport of molecular building blocks and intermediates to enzymatic partners that extend and tailor the growing natural products. Past combinatorial biosynthesis efforts have failed due to incompatible ACP-enzyme pairings. Herein, we report the design of chimeric ACPs with features of the actinorhodin polyketide synthase ACP (ACT) and of the Escherichia coli fatty acid synthase (FAS) ACP (AcpP). We evaluate the ability of the chimeric ACPs to interact with the E. coli FAS ketosynthase FabF, which represents an interaction essential to building the carbon backbone of the synthase molecular output. Given that AcpP interacts with FabF but ACT does not, we sought to exchange modular features of ACT with AcpP to confer functionality with FabF. The interactions of chimeric ACPs with FabF were interrogated using sedimentation velocity experiments, surface plasmon resonance analyses, mechanism-based cross-linking assays, and molecular dynamics simulations. Results suggest that the residues guiding AcpP-FabF compatibility and ACT-FabF incompatibility may reside in the loop I, α-helix II region. These findings can inform the development of strategic secondary element swaps that expand the enzyme compatibility of ACPs across systems and therefore represent a critical step toward the strategic engineering of "un-natural" natural products.

Roles of singleton tryptophan motifs in COPI coat stability and vesicle tethering.

Coat protein I (COPI)-coated vesicles mediate retrograde transport from the Golgi to the endoplasmic reticulum (ER), as well as transport within the Golgi. Major progress has been made in defining the structure of COPI coats, in vitro and in vivo, at resolutions as high as 9 Å. Nevertheless, important questions remain unanswered, including what specific interactions stabilize COPI coats, how COPI vesicles recognize their target membranes, and how coat disassembly is coordinated with vesicle fusion and cargo delivery. Here, we use X-ray crystallography to identify a conserved site on the COPI subunit α-COP that binds to flexible, acidic sequences containing a single tryptophan residue. One such sequence, found within α-COP itself, mediates α-COP homo-oligomerization. Another such sequence is contained within the lasso of the ER-resident Dsl1 complex, where it helps mediate the tethering of Golgi-derived COPI vesicles at the ER membrane. Together, our findings suggest that α-COP homo-oligomerization plays a key role in COPI coat stability, with potential implications for the coordination of vesicle tethering, uncoating, and fusion.

Uncovering protein-protein interactions through a team-based undergraduate biochemistry course.

How can we provide fertile ground for students to simultaneously explore a breadth of foundational knowledge, develop cross-disciplinary problem-solving skills, gain resiliency, and learn to work as a member of a team? One way is to integrate original research in the context of an undergraduate biochemistry course. In this Community Page, we discuss the development and execution of an interdisciplinary and cross-departmental undergraduate biochemistry laboratory course. We present a template for how a similar course can be replicated at other institutions and provide pedagogical and research results from a sample module in which we challenged our students to study the binding interface between 2 important biosynthetic proteins. Finally, we address the community and invite others to join us in making a larger impact on undergraduate education and the field of biochemistry by coordinating efforts to integrate research and teaching across campuses.

Widening the bottleneck: Heterologous expression, purification, and characterization of the Ktedonobacter racemifer minimal type II polyketide synthase in Escherichia coli.

Enzyme assemblies such as type II polyketide synthases (PKSs) produce a wide array of bioactive secondary metabolites. While the molecules produced by type II PKSs have found remarkable clinical success, the biosynthetic prowess of these enzymes has been stymied by 1) the inability to reconstitute the bioactivity of the minimal PKS enzymes in vitro and 2) limited exploration of type II PKSs from diverse phyla. To begin filling this unmet need, we expressed, purified, and characterized the ketosynthase chain length factor (KS-CLF) and acyl carrier protein (ACP) from Ktedonobacter racemifer (Kr). Using E. coli as a heterologous host, we obtained soluble proteins in titers signifying improvements over previous KS-CLF heterologous expression efforts. Characterization of these enzymes reveals that KrACP has self-malonylating activity. Sedimentation velocity analytical ultracentrifugation (SV-AUC) analysis of holo-KrACP and KrKS-CLF indicates that these enzymes do not interact in vitro, suggesting that the acylated state of these proteins might play an important role in facilitating biosynthetically relevant interactions. These results lay important groundwork for optimizing the interaction between KrKS-CLF and KrACP and exploring the biosynthetic potential of other non-actinomycete type II PKSs.

Structure, Regulation, and Inhibition of the Quorum-Sensing Signal Integrator LuxO.

In a process called quorum sensing, bacteria communicate with chemical signal molecules called autoinducers to control collective behaviors. In pathogenic vibrios, including Vibrio cholerae, the accumulation of autoinducers triggers repression of genes responsible for virulence factor production and biofilm formation. The vibrio autoinducer molecules bind to transmembrane receptors of the two-component histidine sensor kinase family. Autoinducer binding inactivates the receptors' kinase activities, leading to dephosphorylation and inhibition of the downstream response regulator LuxO. Here, we report the X-ray structure of LuxO in its unphosphorylated, autoinhibited state. Our structure reveals that LuxO, a bacterial enhancer-binding protein of the AAA+ ATPase superfamily, is inhibited by an unprecedented mechanism in which a linker that connects the catalytic and regulatory receiver domains occupies the ATPase active site. The conformational change that accompanies receiver domain phosphorylation likely disrupts this interaction, providing a mechanistic rationale for LuxO activation. We also determined the crystal structure of the LuxO catalytic domain bound to a broad-spectrum inhibitor. The inhibitor binds in the ATPase active site and recapitulates elements of the natural regulatory mechanism. Remarkably, a single inhibitor molecule may be capable of inhibiting an entire LuxO oligomer.

Sedimentation Velocity Analysis with Fluorescence Detection of Mutant Huntingtin Exon 1 Aggregation in Drosophila melanogaster and Caenorhabditis elegans.

At least nine neurodegenerative diseases that are caused by the aggregation induced by long tracts of glutamine sequences have been identified. One such polyglutamine-containing protein is huntingtin, which is the primary factor responsible for Huntington's disease. Sedimentation velocity with fluorescence detection is applied to perform a comparative study of the aggregation of the huntingtin exon 1 protein fragment upon transgenic expression in Drosophila melanogaster and Caenorhabditis elegans. This approach allows the detection of aggregation in complex mixtures under physiologically relevant conditions. Complementary methods used to support this biophysical approach included fluorescence microscopy and semidenaturing detergent agarose gel electrophoresis, as a point of comparison with earlier studies. New analysis tools developed for the analytical ultracentrifuge have made it possible to readily identify a wide range of aggregating species, including the monomer, a set of intermediate aggregates, and insoluble inclusion bodies. Differences in aggregation in the two animal model systems are noted, possibly because of differences in levels of expression of glutamine-rich sequences. An increased level of aggregation is shown to correlate with increased toxicity for both animal models. Co-expression of the human Hsp70 in D. melanogaster showed some mitigation of aggregation and toxicity, correlating best with inclusion body formation. The comparative study emphasizes the value of the analytical ultracentrifuge equipped with fluorescence detection as a useful and rigorous tool for in situ aggregation analysis to assess commonalities in aggregation across animal model systems.

Self-association motifs in the enteroaggregative Escherichia coli heat-resistant agglutinin 1.

The heat-resistant agglutinin 1 (Hra1) is an integral outer membrane protein found in strains of Escherichia coli that are exceptional colonizers. Hra1 from enteroaggregative E. coli strain 042 is sufficient to confer adherence to human epithelial cells and to cause bacterial autoaggregation. Hra1 is closely related to the Tia invasin, which also confers adherence, but not autoaggregation. Here, we have demonstrated that Hra1 mediates autoaggregation by self-association and we hypothesize that at least some surface-exposed amino acid sequences that are present in Hra1, but absent in Tia, represent autoaggregation motifs. We inserted FLAG tags along the length of Hra1 and used immune-dot blots to verify that four in silico-predicted outer loops were indeed surface exposed. In Hra1 we swapped nine candidate motifs in three of these loops, ranging from one to ten amino acids in length, to the corresponding sequences in Tia. Three of the motifs were required for Hra1-mediated autoaggregation. The database was searched for other surface proteins containing these motifs; the GGXWRDDXK motif was also present in a surface-exposed region of Rck, a Salmonella enterica serotype Typhimurium complement resistance protein. Cloning and site-specific mutagenesis demonstrated that Rck can confer weak, GGXWRDDXK-dependent autoaggregation by self-association. Hra1 and Rck appear to form heterologous associations and GGXWRDDXK is required on both molecules for Hra1-Rck association. However, a GGYWRDDLKE peptide was not sufficient to interfere with Hra1-mediated autoaggregation. In the present study, three autoaggregation motifs in an integral outer membrane protein have been identified and it was demonstrated that at least one of them works in the context of a different cell surface.

Probing the selectivity of ß-hydroxylation reactions in non-ribosomal peptide synthesis using analytical ultracentrifugation.

Bacteria and fungi use non-ribosomal peptide synthetases (NRPSs) to produce peptides of broad structural diversity and biological activity, many of which have proven to be of great importance for human health. The impressive diversity of non-ribosomal peptides originates in part from the action of tailoring enzymes that modify the structures of single amino acids and/or the mature peptide. Studying the interplay between tailoring enzymes and the peptidyl carrier proteins (PCPs) that anchor the substrates is challenging owing to the transient and complex nature of the protein-protein interactions. Using sedimentation velocity (SV) methods, we studied the collaboration between the PCPs and cytochrome P450 enzyme that results in the installation of ß-hydroxylated amino acid precursors in the biosynthesis of the depsipeptide skyllamycin. We show that SV methods developed for the analytical ultracentrifuge are ideally suited for a quantitative exploration of PCP-enzyme equilibrium interactions. Our results suggest that the PCP itself and the presence of substrate covalently tethered to the PCP together facilitate productive PCP-P450 interactions, thereby revealing one of nature's intricate strategies for installing interesting functionalities using natural product synthetases.

Effect of helix length on the stability of the Lac repressor antiparallel coiled coil.

The helix length dependence of the stability of antiparallel four-chain coiled coils is investigated using eight synthetic peptides (Lac21-Lac28) whose sequences are derived from the tetramerization domain of the Lac repressor protein. Previous studies using analytical ultracentrifugation sedimentation equilibrium experiments to characterize Lac21 and Lac28 justifies the use of a two state model to describe the unfolding behavior of these two peptides. Using circular dichroism spectropolarimetry as a measure of tetramer assembly, both chemical and thermal denaturation experiments were carried out to determine thermodynamic parameters. We found that the hydrophobic core residues provide the greatest impact on stability and, as a consequence, must reorganize the register of the antiparallel helices to accommodate the burial of the nonpolar amino acids. Addition of noncore residues appears to have only a minor effect on stability, and in some cases, show a slight destabilization.

Role of the coiled-coil structural motif in polyglutamine aggregation.

Polyglutamine repeat motifs are known to induce protein aggregation in various neurodegenerative diseases, and flanking sequences can modulate this behavior. It has been proposed that the 17 N-terminal residues (Htt(NT)) of the polyglutamine-containing huntingtin protein accelerate the kinetics of aggregation due to the formation of helix-rich oligomers through helix-pairing interactions. Several hypotheses that explain the role of helical interactions in modulating aggregation have been proposed. These include (1) an increase in the effective concentration of polyglutamine chains (proximity model), (2) the induction of helical structure within the polyglutamine domain itself (transformation model), and/or (3) interdomain interactions between the flanking sequence and the polyglutamine domain (domain cross-talk model). These hypotheses are tested by studying the kinetics of polyglutamine aggregation using a Q25 sequence fused to a well-defined heterotetrameric coiled-coil model system. Using a combined spectroscopic and dye binding approach, it is shown that stable coiled-coil formation strongly inhibits polyglutamine aggregation, suggesting that the proximity and transformation models are insufficient to explain the enhanced aggregation seen in Htt(NT)-polyglutamine constructs. Consistent with other published work, our data support a model in which domain cross-talk prevents formation of a nonspecific aggregated collapsed polyglutamine state, which can act to inhibit conversion to a fibrillar state. Because our model system has a charged to nonpolar residue ratio much higher than that of the Htt(NT) sequence, domain cross-talk is severely weakened, thus favoring the nonspecific aggregation pathway and significantly inhibiting aggregation through a fibrillar pathway.

Effect of helical flanking sequences on the morphology of polyglutamine-containing fibrils.

A peptide model system has been developed to study the effects of helical flanking sequences on polyglutamine aggregation. In a companion manuscript, the kinetics of aggregation are described, comparing the influence of a well-defined heterotetrameric coiled coil to that of the helix-rich structure found in Htt(NT), a 17-residue flanking sequence found in the huntingtin protein, on polyglutamine aggregation. Here, the morphological characterization of the resultant fibrils that form for a set of peptides is reported, only one of which, KKQ25KK, has been previously studied. A careful analysis of TEM and AFM images of KKQ25KK confirms that it forms bundled fibrils of varying length and reveals, unexpectedly, that they are composed of fully extended cross-ß-strands. Second, it is shown that helical flanking sequences do not disrupt the assembly of a core cross-ß-sheet structure, but such flanking sequences can influence higher order processes, such as inhibiting the bundling of the fibrils.

Testing the role of charge and structure on the stability of peptide-porphyrin complexes.

This study aims to extend a structural and biophysical understanding of a coiled-coil based peptide model system that serves as a scaffold for the anionic porphyrin, TPPS4. This is part of an ongoing biomaterials effort to create photoelectronically active mesoscale fibrils for surface deposition and characterization of conductivity properties. The goals are two-fold: (1) to explore optimal basic side-chain moieties for tight binding to TPPS4 and (2) to test the binding of various metalated TPPS4 derivatives to our peptide model system. The latter goal is to control the electronic and redox properties of the fibrillar biomaterials. A soluble version of the peptide biomaterial was used in order to probe binding and to extract thermodynamically rigorous equilibrium binding constants. UV-visible spectroscopy and circular dichroism spectropolarimtery are used to measure the effects of binding on the Soret band of the porphyrin and the helical signal of the peptide, respectively. For the first study, it was found that lysine, ornithine, and arginine are equally robust at engaging TPPS4 with low micromolar binding affinity. In the case of the metalated porphyrins, submicromolar binding affinity was observed for Cu(II), Ni(II), and Pd(II). The ability of these metalated porphyrins to bind with high affinity is dependent largely on structural perturbations of the porphyrin molecule, rather than on induced electronic effects.

Effect of glutamate side chain length on intrahelical glutamate-lysine ion pairing interactions.

Ion pairing interactions between oppositely charged amino acids are important for protein structure stability. Despite the apparent electrostatic nature of these interactions, the charged amino acids Lys, Arg, Glu, and Asp have a different number of hydrophobic methylenes linking the charged functionality to the backbone. To investigate the effect of Glu (and Asp) side chain length on ion pairing interactions, a series of 36 monomeric α-helical peptides containing Zbb-Xaa (i, i+3), (i, i+4), and (i, i+5) (Zbb = Aad, Glu, Asp; Xaa = Lys, Orn, Dab, Dap) sequence patterns were studied by circular dichroism (CD) spectroscopy at pH 7 and 2. Peptides with Glu and Aad exhibited similar helicity and pH dependence, whereas peptides with Asp behaved distinctly different. The side chain interaction energetics were derived from the CD data using the nesting block method coupled with modified Lifson-Roig theory. At pH 7, no Zbb-Xaa (i, i+5) interaction was observed, regardless of side chain length (consistent with the helix geometry). Interestingly, only Lys was capable of supporting Zbb-Xaa (i, i+3) interactions, whereas any Xaa side chain length supported Zbb-Xaa (i, i+4) interactions. In particular, the magnitude of both Zbb(-)-Lys (i, i+4) and Zbb(-)-Orn (i, i+4) interaction energies followed the trend Asp > Glu > Aad. Side chain conformational analysis by molecular mechanics calculations showed that the Zbb-Xaa (i, i+3) interactions involved the χ(1) dihedral combination (g+, g+) for the i and i+3 residues, whereas the Zbb-Xaa (i, i+4) interactions were supported by the χ(1) dihedral combination (t, g+) for the i and i+4 residues. These calculated low energy conformers were consistent with conformations of intrahelical Asp-Lys and Glu-Lys salt bridges in a nonredundant protein structure database. These results suggest that Asp and Glu provide natural variation, and lengthening the Glu side chain further to Aad does not furnish additional characteristics that Glu cannot supply.

Thermodynamic analysis of self-assembly in coiled-coil biomaterials.

Coiled-coil protein structural motifs have proven amenable to the design of structurally well-defined biomaterials. Mesoscale structural properties can be fairly well predicted based on rules governing the chemical interactions between the helices that define this structural motif. We explore the role of the hydrophobic core residues on the self-assembly of a coiled-coil polymer through a mutational analysis coupled with a salting-out procedure. Because the resultant polymers remain in solution, a thermodynamic approach is applied to characterize the polymer assembly using conventional equations from polymer theory to extract nucleation and elongation parameters. The stabilities and lengths of the polymers are measured using circular dichroism spectropolarimetry, sizing methods including dynamic light scattering and analytical ultracentrifugation, and atomic force microscopy to assess mesoscale morphology. Upon mutating isoleucines at two core positions to serines, we find that polymer stability is decreased while the degree of polymerization is about the same. Differences in results from circular dichroism and dynamic light scattering experiments suggest the presence of a stable intermediate state, and a scheme is proposed for how this intermediate might relate to the monomer and polymer states.

Characterization of mesoscale coiled-coil peptide-porphyrin complexes.

Photoelectronically conductive self-assembling peptide-porphyrin assemblies have great potential in their use as biomaterials, owing largely to their environmentally responsive properties. We have successfully designed a coiled-coil peptide that can self-assemble to form mesoscale filaments and serve as a scaffold for porphyrin interaction. In our earlier work, peptide-porphyrin-based biomaterials were formed at neutral pH, but the structures were irregular at the nano- to microscale size range, as judged by atomic force microscopy. We identified a pH in which mesoscale fibrils were formed, taking advantage of the types of porphyrin interactions that are present in well-characterized J-aggregates. We used UV-visible spectroscopy, circular dichroism spectropolarimetry, fluorescence spectroscopy, and atomic force microscopy to characterize these self-assembling biomaterials. We propose a new assembly paradigm that arises from a set of unique porphyrin-porphyrin and porphyrin-peptide interactions whose structure may be readily modulated by changes in pH or peptide concentration.

Positional effects on helical Ala-based peptides.

Helix-coil equilibrium studies are important for understanding helix formation in protein folding, and for helical foldamer design. The quantitative description of a helix using statistical mechanical models is based on experimentally derived helix propensities and the assumption that helix propensity is position-independent. To investigate this assumption, we studied a series of 19-residue Ala-based peptides, to measure the helix propensity for Leu, Phe, and Pff at positions 6, 11, and 16. Circular dichroism spectroscopy revealed that substituting Ala with a given amino acid (Leu, Phe, or Pff) resulted in the following fraction helix trend: KXaa16 > KXaa6 > KXaa11. Helix propensities for Leu, Phe, and Pff at the different positions were derived from the CD data. For the same amino acid, helix propensities were similar at positions 6 and 11, but much higher at position 16 (close to the C-terminus). A survey of protein helices revealed that Leu/Phe-Lys (i, i + 3) sequence patterns frequently occur in two structural patterns involving the helix C-terminus; however, these cases include a left-handed conformation residue. Furthermore, no Leu/Phe-Lys interaction was found except for the Lys-Phe cation-π interaction in two cases of Phe-Ala-Ala-Lys. The apparent high helix propensity at position 16 may be due to helix capping, adoption of a 310-helix near the C-terminus perhaps with Xaa-Lys (i, i + 3) interactions, or proximity to the peptide chain terminus. Accordingly, helix propensity is generally position-independent except in the presence of alternative structures or in the proximity of either chain terminus. These results should facilitate the design of helical peptides, proteins, and foldamers.

Polyglutamine fibrils are formed using a simple designed beta-hairpin model.

Polyglutamine repeats are found in proteins associated with many neurodegenerative diseases. These repeats are responsible for intracellular protein aggregation that resemble amyloid plaques and contain the hallmarks of cross-beta fibrillar structures. Recent work has suggested that the glutamines are involved in aggregation through two possible mechanisms: one involving only side-chain hydrogen bonding and a second involving interdigitation of the glutamines with tight van der Waal's packing (steric zipper model). We are interested in determining which interactions are particularly involved in early assembly processes and have developed a beta-hairpin model system to address this problem. Our model system is designed to stabilize a putative high-energy nucleating structure to provide a window to view early assembly processes. We have applied spectroscopy tools (circular dichroism, infrared, and dynamic light scattering) to probe the self-assembly of beta-sheet fibrils. These experiments established the conditions to study fibrillar morphology using atomic force microscopy. We show that fibrils are short with minimal lateral growth, suggesting that this may be a good model system for studying early assembly steps.

Production and analysis of a mammalian septin hetero-octamer complex.

The septins are filament-forming proteins found in diverse eukaryotes from fungi to vertebrates, with roles in cytokinesis, shaping of membranes and modifying cytoskeletal organization. These GTPases assemble into rod-shaped soluble hetero-hexamers and hetero-octamers in mammals, which polymerize into filaments and higher order structures. While the cell biology and pathobiology of septins are advancing rapidly, mechanistic study of the mammalian septins is limited by a lack of recombinant hetero-octamer materials. We describe here the production and characterization of a recombinant mammalian septin hetero-octamer of defined stoichiometry, the SEPT2/SEPT6/SEPT7/SEPT3 complex. Using a fluorescent protein fusion to the complex, we observed filaments assembled from this complex. In addition, we used this novel tool to resolve recent questions regarding the organization of the soluble septin complex. Biochemical characterization of a SEPT3 truncation that disrupts SEPT3-SEPT3 interactions is consistent with SEPT3 occupying a central position in the complex while the SEPT2 subunits are at the ends of the rod-shaped octameric complexes. Consistent with SEPT2 being on the complex ends, we find that our purified SEPT2/SEPT6/SEPT7/SEPT3 hetero-octamer copolymerizes into mixed filaments with separately purified SEPT2/SEPT6/SEPT7 hetero-hexamer. We expect this new recombinant production approach to lay essential groundwork for future studies into mammalian septin mechanism and function.

Effect of highly fluorinated amino acids on protein stability at a solvent-exposed position on an internal strand of protein G B1 domain.

Highly fluorinated amino acids have been used to stabilize helical proteins for potential application in various protein-based biotechnologies. However, many proteins used for therapeutics and biosensors involve beta-sheet proteins such as antibodies. Accordingly, we explored the effect of several highly fluorinated amino acids on beta-sheet stability including (S)-2-amino-4,4,4-trifluorobutyric acid (Atb), (S)-5,5,5',5'-tetrafluoroleucine (Qfl), (S)-5,5,5,5',5',5'-hexafluoroleucine (Hfl), and (S)-pentafluorophenylalanine (Pff). Nine proteins based on the protein G B1 domain I6A T44A mutant (GB1) with various amino acids at the solvent exposed guest position 53 in the internal strand 4 were synthesized, purified, and investigated by thermal denaturation monitored by circular dichroism spectroscopy. Based on the thermal denaturation data, GB1 stability is affected by the amino acid at the guest position 53. Apparently, introducing fluorine results in more stable GB1 mutants (Pff > Phe, Hfl > Qfl > Leu, Atb > Abu). In particular, GB1 becomes more stable upon introducing fluorines by up to 0.35 kcal x mol(-1) x residue(-1). Overall, these results suggest that fluoro-amino acids may be worthwhile building blocks to explore for stabilizing beta-sheet proteins, which are especially important for biotechnologies such as protein therapeutics and biosensors.

The plasmid-encoded regulator activates factors conferring lysozyme resistance on enteropathogenic Escherichia coli strains.

We demonstrate that enhanced lysozyme resistance of enteropathogenic Escherichia coli requires the plasmid-encoded regulator, Per, and is mediated by factors outside the locus for enterocyte effacement. EspC, a Per-activated serine protease autotransporter protein, conferred enhanced resistance on nonpathogenic E. coli, and a second Per-regulated, espC-independent lysozyme resistance mechanism was identified.