Expression and characterization of delayed rectifying K+ channels in anterior rat taste buds

Delayed rectifying K⁺ (DRK) channels in taste cells have been implicated in the regulation of cell excitability and as potential targets for direct and indirect modulation by taste stimuli. In the present study, we have used patch-clamp recording to determine the biophysical properties and pharmacological sensitivity of DRK channels in isolated rat fungiform taste buds. Molecular biological assays at the taste bud and single-cell levels are consistent with the interpretation that taste cells express a variety of DRK channels, including members from each of the three major subfamilies: KCNA, KCNB, and KCNC. Real-time PCR assays were used to quantify expression of the nine DRK channel subtypes. While taste cells express a number of DRK channels, the electrophysiological and molecular biological assays indicate that the Shaker Kv1.5 channel (KCNA5) is the major functional DRK channel expressed in the anterior rat tongue. transduction     

Novel immunoglobulin-like transcripts in teleost fish encode polymorphic receptors with cytoplasmic ITAM or ITIM and a new structural Ig domain similar to the natural cytotoxicity receptor NKp44

Members of the immunoglobulin superfamily (IgSF) include a group of innate immune receptors located in the leukocyte receptor complex (LRC) and other small clusters such as the TREM/NKp44 cluster. These receptors are characterised by the presence of immunoglobulin domains, a stalk, a transmembrane domain, and a cytoplasmic region containing either an immunoreceptor tyrosine-based inhibitory motif (ITIM) or are linked to an adapter molecule with an activation motif (ITAM) for downstream signalling. We have isolated two carp cDNA sequences encoding receptors in which the extracellular Ig domain structurally resembles the novel V-type Ig domain of NKp44. This is supported by a homology model. The cytoplasmic regions contain either an ITAM (Cyca-NILT1) or ITIMs (Cyca-NILT2). The tissue expression of these receptors is nearly identical, with the highest expression in the immunological organs. Peripheral blood leucocytes showed no detectable expression, but upon in vitro culture expressed NILT1, the activating receptor, and not the inhibitory NILT2 receptor. Southern blot analysis indicated that the NILT1 and NILT2 sequences belong to a multigene family. Analysis of the NILT Ig domain-encoding sequences amplified from both genomic DNA and cDNA revealed extensive haplotypic and allelic polymorphism. Database mining of the zebrafish genome identified several homologs on Chromosome 1, which also contains a cluster of class I major histocompatibility genes. This constellation is reminiscent of the TREM/NKp44 gene cluster and the HLA complex located on human Chromosome 6. The carp NILT genes form a unique cluster of innate immune receptors, which are highly polymorphic, and characterised by a new Ig structural subfamily and are distinct from the novel immune-type receptors (Nitrs) found in other fish species.     

In situ product removal using a crystallization loop in asymmetric reduction of 4-oxoisophorone by Saccharomyces cerevisiae

In situ product crystallization was investigated for solid product crystals that were obtained during fermentation. The model reaction was the asymmetric reduction of 4-oxoisophorone (OIP) using baker's yeast (S. cerevisiae) as a biocatalyst. The target product was 6R-dihydro-oxoisophorone (DOIP), also known as levodione, a key intermediate in carotenoid synthesis. DOIP was degraded by baker's yeast mainly to (4S,6R)-actinol, an unwanted byproduct in the process. Actinol formation reached up to 12.5% of the initial amount of OIP in the reactor during a batch process. However, better results were obtained when the dissolved DOIP concentration was controlled using an integrated fermentation-crystallization process because: (a) actinol formation was reduced to 4%; and (b) DOIP crystal formation in the reactor was avoided. DOIP productivity was improved by 50% and its selectivity was raised from 87% to 96% relative to the batch process. In the integrated process, most of the product was recovered as pure crystals; this may already minimize, if not eliminate, the need for organic solvents in the final purification steps. An almost sixfold reduction in biocatalyst consumption per kilogram product was achieved, which also can contribute to the minimization of waste streams.     

Degradation of mutated bovine pancreatic trypsin inhibitor in the yeast vacuole suggests post-endoplasmic reticulum protein quality control

The rate-limiting step in protein secretion is folding, which occurs in the endoplasmic reticulum (ER) lumen, and almost all secreted proteins contain disulfide bonds that form in the ER and stabilize the native state. Secreted proteins unable to fold may aggregate or they may be subject to ER-associated protein degradation. To examine the fate of aberrant forms of a well characterized, disulfide-bonded secreted protein, we expressed bovine pancreatic trypsin inhibitor in yeast. Bovine pancreatic trypsin inhibitor is a single domain, 58-amino acid polypeptide containing three disulfide bonds, and yeast cells secrete the wild type protein. In contrast, the Y35L mutant, which folds rapidly but is unstable, remains soluble and is not secreted. Surprisingly, the proteolysis of Y35L is unaffected in yeast containing mutations in genes encoding factors required for ER-associated protein degradation and is stable if artificially retained in the ER. Rather, Y35L is diverted from the Golgi to the vacuole and degraded. Because only the mutant protein is quantitatively proteolyzed these data suggest that a post-ER quality control check-point diverts unstable proteins to the vacuole for degradation.     

Ultra-fast evaluation of protein energies directly from sequence

The structure, function, stability, and many other properties of a protein in a fixed environment are fully specified by its sequence, but in a manner that is difficult to discern. We present a general approach for rapidly mapping sequences directly to their energies on a pre-specified rigid backbone, an important sub-problem in computational protein design and in some methods for protein structure prediction. The cluster expansion (CE) method that we employ can, in principle, be extended to model any computable or measurable protein property directly as a function of sequence. Here we show how CE can be applied to the problem of computational protein design, and use it to derive excellent approximations of physical potentials. The approach provides several attractive advantages. First, following a one-time derivation of a CE expansion, the amount of time necessary to evaluate the energy of a sequence adopting a specified backbone conformation is reduced by a factor of 10(7) compared to standard full-atom methods for the same task. Second, the agreement between two full-atom methods that we tested and their CE sequence-based expressions is very high (root mean square deviation 1.1-4.7 kcal/mol, R2 = 0.7-1.0). Third, the functional form of the CE energy expression is such that individual terms of the expansion have clear physical interpretations. We derived expressions for the energies of three classic protein design targets-a coiled coil, a zinc finger, and a WW domain-as functions of sequence, and examined the most significant terms. Single-residue and residue-pair interactions are sufficient to accurately capture the energetics of the dimeric coiled coil, whereas higher-order contributions are important for the two more globular folds. For the task of designing novel zinc-finger sequences, a CE-derived energy function provides significantly better solutions than a standard design protocol, in comparable computation time. Given these advantages, CE is likely to find many uses in computational structural modeling.     

Chargeability measurements of selected pharmaceutical dry powders to assess their electrostatic charge control capabilities

The purpose of this study was to develop an instrument (the Purdue instrument) and the corresponding methodologies to measure the electrostatic charge development (chargeability) of dry powders when they are in dynamic contact with stainless steel surfaces. The system used an inductive noncontact sensor located inside an aluminum Faraday cage and was optimized to measure the charging capabilities of a fixed volume of powder (0.5 cc). The chargeability of 5,5-diphenyl-hydantoin, calcium sulfate dihydrate, cimetidine, 3 grades of colloidal silicon dioxide, magnesium stearate, 4 grades of microcrystalline cellulose, salicylic acid, sodium carbonate, sodium salicylate, spray-dried lactose, and sulfin-pyrazone were tested at 4 linear velocities, and the particle size distribution effect was assessed for 3 different grades of colloidal silicon dioxide and 4 different grades of micro-crystalline cellulose. The chargeability values exhibited a linear relationship for the range of velocities studied, with colloidal silicon dioxide exhibiting the maximum negative chargeability and with spray-dried lactose being the only compound to exhibit positive chargeability. The instrument sensitivity was improved by a factor of 2 over the first generation version, and the electrostatic charge measurements were reproducible with relative standard deviations ranging from nondetectable to 33.7% (minimum of 3 replicates). These results demonstrate the feasibility of using the Purdue instrument to measure the electrostatic charge control capabilities of pharmaceutical dry powders with a reasonable level of precision.     

Conservation of Structure and Protein-Protein Interactions Mediated by the Secreted Mycobacterial Proteins EsxA,EsxB, and EspA

Mycobacterium tuberculosis EsxA and EsxB proteins are founding members of the WXG100 (WXG) protein family, characterized by their small size (∼100 amino acids) and conserved WXG amino acid motif. M. tuberculosis contains 11 tandem pairs of WXG genes; each gene pair is thought to be coexpressed to form a heterodimer. The precise role of these proteins in the biology of M. tuberculosis is unknown, but several of the heterodimers are secreted, which is important for virulence. However, WXG proteins are not simply virulence factors, since nonpathogenic mycobacteria also express and secrete these proteins. Here we show that three WXG heterodimers have structures and properties similar to those of the M. tuberculosis EsxBA (MtbEsxBA) heterodimer, regardless of their host species and apparent biological function. Biophysical studies indicate that the WXG proteins from M. tuberculosis (EsxG and EsxH), Mycobacterium smegmatis (EsxA and EsxB), and Corynebacterium diphtheriae (EsxA and EsxB) are heterodimers and fold into a predominately α-helical structure. An in vivo protein-protein interaction assay was modified to identify proteins that interact specifically with the native WXG100 heterodimer. MtbEsxA and MtbEsxB were fused into a single polypeptide, MtbEsxBA, to create a biomimetic bait for the native heterodimer. The MtbEsxBA bait showed specific association with several esx-1-encoded proteins and EspA, a virulence protein secreted by ESX-1. The MtbEsxBA fusion peptide was also utilized to identify residues in both EsxA and EsxB that are important for establishing protein interactions with Rv3871 and EspA. Together, the results are consistent with a model in which WXG proteins perform similar biological roles in virulent and nonvirulent species.The WXG100 (WXG; pfam06013) proteins are a class of effector molecules found in gram-positive bacteria (26). WXG proteins are characterized by their small size (∼ 100 amino acids [aa]) and the presence of a WXG motif, or its structural equivalent, near the midpoint of their primary sequence (26). Bioinformatic analyses have shown that one WXG gene is frequently positioned near, or directly adjacent to, a second, related, WXG gene (14). The gene pairs characterized thus far encode proteins that associate to form 1:1 complexes (20, 31). The WXG proteins were once thought to be restricted to the mycobacteria, but homologues have now been detected in species of Bacillus, Listeria, Streptomyces, and Corynebacterium, among others, and the Pfam server lists >89 distinct WXG-encoding species and strains (10).The identification of WXG proteins encoded by the pathogens Mycobacterium tuberculosis (15, 17, 19, 36), Mycobacterium marinum (13), and Staphylococcus aureus (5) has created significant interest in the proteins'' biological activity. Nevertheless, these proteins are not a priori virulence factors (39), since organisms expressing WXG proteins are not necessarily capable of causing disease. In addition to pathogenesis, the WXG proteins are associated with processes as disparate as zinc homeostasis (24) and conjugal gene transfer (9, 11). A model for the mechanism(s) of action of these proteins that includes an explanation for their apparent functional versatility is at present lacking. One reason for this ambiguity may be the near-absence of studies comparing virulence-associated and non-virulence-associated WXG proteins, which is a goal of this study.The M. tuberculosis secreted virulence factors EsxA (also called ESAT-6, or Rv3875) and EsxB (CFP-10; Rv3874) are the founding members of the WXG family, and M. tuberculosis derivatives defective in EsxA and EsxB are attenuated (17, 19, 36). The results of biochemical and structural studies indicate that EsxA and EsxB form a tightly associated heterodimer, EsxAB (25, 30, 31). The M. tuberculosis genome contains 23 WXG genes, named esxA to esxW, and the majority of these are expressed as tandem pairs (26). Of the pairs, five, including esxA and esxB, are contained within larger, highly conserved genetic loci, called esx-1 to esx-5 (Fig. ​(Fig.1).1). These loci have been the focus of much research, since mutants of esx-1 are attenuated, and esx-3 and esx-5 are necessary for in vitro growth of M. tuberculosis and M. marinum (1, 2, 32-34). The esx loci are proposed to encode secretory apparatuses dedicated to the secretion of their cognate WXG proteins (1).Open in a separate windowFIG. 1.Genetic map of the esx-1 loci of M. tuberculosis and M. smegmatis. The M. tuberculosis esx-1 genes discussed in the text are indicated by white arrows, as are their M. smegmatis homologues. The M. tuberculosis map also shows the Rv3884 and Rv3885 genes, which are part of the adjacent esx-2 locus. pRD1-2F9 is the cosmid that was used to create an esx-1-specific prey library. pRD1-2F9 includes the Rv3860 to Rv3885 genes, thus encompassing the entire esx-1 locus and part of esx-2. The four genes below the M. smegmatis map include defective insertion sequences (ISs) inserted into MSMEG_0075.Although the majority of genes required for the secretion of the EsxAB heterodimer are encoded from within esx-1, additional non-esx-1 genes are necessary for secretion. In particular, one M. tuberculosis locus, esp, encodes three proteins essential for EsxAB secretion (12, 23). The first gene of the operon encodes a protein, EspA, that is cosecreted with EsxAB via the ESX-1 apparatus (12). Although no direct physical evidence has been presented, the inference from the interdependent cosecretion of the three proteins is that they likely form a complex, which is secreted by the ESX-1 apparatus. In this paper we provide the first genetic evidence that these three proteins interact.The lack of a genetic assay for the study of ESX-1 activity in M. tuberculosis has hindered the identification of all of the protein components of the apparatus and all of the substrates that it secretes. However, the fast-growing, nonpathogenic organism Mycobacterium smegmatis has a conserved esx-1 locus that is essential for DNA transfer, and we have exploited this requirement for genetic studies (9). These analyses have shown that the M. smegmatis ESX-1 apparatus is functionally related to that of M. tuberculosis (11) and that M. smegmatis encodes non-esx-1 genes necessary for the secretion of the EsxAB heterodimer, including orthologues of EspA (9).Here we have examined whether the secondary and quaternary structures of M. tuberculosis EsxA and EsxB are prototypical for other, functionally distinct and evolutionarily distant members of the WXG family (Fig. ​(Fig.2A).2A). Comparisons were made to homologues encoded by M. smegmatis (esxA and esxB), Corynebacterium diphtheriae (esxA and esxB), and an additional non-virulence-related pair from M. tuberculosis (esxG and esxH, encoded from the esx-3 locus). Structural characterization of these proteins establishes that their secondary and quaternary structures are conserved, with each pair folding into a predominately α-helical structure and associating to form a heterodimer. We next devised and tested the utility of a novel strategy to identify proteins that interact specifically with these WXG heterodimers. This involved fusing EsxB and EsxA to create a biomimetic heterodimer for use in mycobacterial two-hybrid experiments. We reasoned that the use of this unique bait would allow the detection of proteins that interact with both components of the native heterodimer and that these proteins would normally go undetected in the conventional, single-protein two-hybrid screens. Indeed, using this approach, we identified novel protein partners of M. tuberculosis EsxBA (MtbEsxBA). We show for the first time that EspA proteins from M. tuberculosis and M. smegmatis interact with the EsxBA heterodimer (from both species) but not with EsxA or EsxB alone. We also provide evidence for promiscuity between the different M. tuberculosis ESX apparatuses by showing that EsxBA, encoded by esx-1, can interact with Esx proteins encoded by esx-2. Taken together, our studies suggest that the WXG proteins possess similar structures and properties, regardless of the host species and the apparent biological function.Open in a separate windowFIG. 2.Sequence alignment of WXG proteins characterized in this study and the strategy used to facilitate their expression. (A) Amino acid sequence alignment of four pairs of WXG proteins. Conserved sequences are in boldface, and the signature WXG motif is indicated with asterisks. Three residues in Rv3874 (EsxB) and a single residue in Rv3875 (EsxA) are underlined; they are the sites of amino acid substitutions discussed in the text that abrogate Rv3871 interactions. (B) (Bottom) Scheme for coexpression of tandemly arranged WXG genes. (Top) The ribbon cartoon (30) shows how the two monomers are freed from the expressed fusion protein by thrombin cleavage (scissors) at the peptide tether (balls and sticks).     

Directed evolution of the epidermal growth factor receptor extracellular domain for expression in yeast

The extracellular domain of epidermal growth factor receptor (EGFR-ECD) has been engineered through directed evolution and yeast surface display using conformationally-specific monoclonal antibodies (mAbs) as screening probes for proper folding and functional expression in Saccharomyces cerevisiae. An EGFR mutant with four amino acid changes exhibited binding to the conformationally-specific mAbs and human epidermal growth factor, and showed increased soluble secretion efficiency compared with wild-type EGFR. Full-length EGFR containing the mutant EGFR-ECD was functional, as assayed by EGF-dependent autophosphorylation and intracellular MAPK signaling in mammalian cells, and was expressed and localized at the plasma membrane in yeast. This approach should enable engineering of other complex mammalian receptor glycoproteins in yeast for genetic, structural, and biophysical studies.     

In situ product recovery (ISPR) by crystallization: basic principles, design, and potential applications in whole-cell biocatalysis

The removal of inhibiting or degrading product from a bioreactor as soon as the product is formed is an important issue in industrial bioprocess development. In this review, the potential of crystallization as an in situ product removal (ISPR) technique for the biocatalytic production of crystalline compounds is discussed. The emphasis of this review is on the current status of crystalline product formation by metabolically active cells for application in fine-chemicals production. Examples of relevant biocatalytic conversions are summarized, and some basic process options are discussed. Furthermore, a case study is presented in which two conceptual process designs are compared. In one process, product formation and crystallization are integrated by applying ISPR, whereas a second, nonintegrated process is based on a known conventional process equivalent for the production of 6R-dihydro-oxoisophorone. The comparison indicates that employing ISPR leads to significant advantages over the nonintegrated case in terms of increased productivity and yield with a corresponding decrease in the number of downstream processing steps, as well as in the quantity of waste streams. This leads to an economically more interesting process alternative. Finally, a general outlook on the various research aspects of ISPR by crystallization is given.