Biochemical Comparison of Tpm1.1 (α) and Tpm2.2 (ß) Tropomyosins from Rabbit Skeletal Muscle.

Tpm1.1 (α) and Tpm2.2 (ß) tropomyosins (39 amino acid substitutions) were isolated from adult rabbit skeletal muscle without chemical modification of cysteine, with negligible phosphorylation as assessed by two-dimensional polyacrylamide gel electrophoresis, and characterized biochemically. Reconstituted skeletal thin filaments composed of Tpm2.2 produce ∼30% less Ca(II)-induced activation of the steady-state actomyosin-S1MgATPase rate than Tpm1.1 does. This is observed at a high S1/actin ratio (6 µM myosin-S1A1, 3 µM thin filaments, pCa 4) and as a function of pCa (0.3 µM myosin-S1A1, 25 µM thin filaments). The two pCa versus MgATPase relationships are similar in terms of their steepness and midpoint. Isotype has a bearing on self-polymerization and interaction with troponin. Solutions (pH 7, ionic strength of ∼30 mM) of Tpm2.2 are more viscous than solutions of Tpm1.1, an observation explained by substitutions at the carboxy-terminal end of the molecule, including His276Asn and Met281Ile. Conversely, the enhancement of viscosity of Tpm1.1 by skeletal troponin is greater than that for Tpm2.2. Further, Tpm1.1 binds more strongly than Tpm2.2 to skeletal troponin-Sepharose, as evidenced by a later elution position in the salt gradient. Mixtures of tropomyosin and the amino-terminal CNBr fragment of troponin-T, CB1 (residues 1-151), were chromatographed on a size exclusion column in the presence of different concentrations of KCl. In 0.1 M salt, CB1 co-elutes with either isoform but is largely dissociated at 0.22 M. At intermediate salt concentrations, different degrees of complexation are observed, more extensive for Tpm1.1 than for Tpm2.2. Thus, the first reported variants of tropomyosin are distinct in their interactive and functional properties. The biochemical properties of Tpm2.2 are of particular relevance to the immature skeletal muscle thin filament.

A laboratory exercise to illustrate protein-membrane interactions.

The laboratory protocol presented here takes about 3 hours to perform and investigates protein and lipid interactions. Students first purify His6 -tagged human apolipoprotein A-I (apoA-I) with Ni-NTA affinity resin in a simple batch protocol and prepare multilamellar vesicles (MLV) from pre-dried phospholipid films. When apoA-I is added to the MLV, much smaller protein/lipid nanodisc complexes are formed in some instances. Nanodisc formation can be monitored by a decrease in light-scattering intensity at 340 nm using a simple spectrophotometer. Students will observe nanodisc formation with MLV formed from the anionic phospholipid dimyristoylphosphatidyl glycerol, which pack poorly into lipid bilayers, but not with MLV formed from the zwitterionic phospholipid dimyristoyl phosphatidylcholine, which form stable bilayers. This laboratory exercise is accompanied by questions and exercises that enable students a deeper of the dimensions of apoA-I and nanodiscs as well as the biological relevance of nanodisc formation in the process of reverse cholesterol transport.

The potential of biodetoxification activity as a probiotic property of Lactobacillus reuteri.

Previous work on the metabolism of Lactobacillus reuteri ATCC 55730 anticipated a variability in the use of organic electron acceptors as a means to relieve metabolic redox problems. Therefore, investigations focusing on this unique metabolism of L. reuteri may reveal a basis for new probiotic properties. For instance, L. reuteri may use reactive aldehydes and ketones as electron acceptors to balance their redox metabolism, which opens the possibility to exploit this bacterium for in vivo bioreduction of deleterious compounds in the gastrointestinal tract (GIT). Herein we demonstrate that L. reuteri ATCC 55730 cultures on glucose are able to use furfural (1g/L), and hydroxymethylfurfural (HMF) (0.5g/L), as electron acceptors. The former enhances the growth rate by about 25% and biomass yield by 15%, whereas the latter is inhibitory. Furfural is stoichiometrically reduced to furfuryl alcohol by the culture. The conversion of furfural had no effect on the flux distribution between the simultaneously operating phosphoketolase and Embden-Meyerhof pathways, but initiated a flux to acetate production. In addition to furfural and HMF, cellular extracts showed potential to reoxidize NADH and/or NADPH with acrolein, crotonaldehyde, and diacetyl, indicating that conversion reactions take place intracellularly, however, utilization mechanisms for the latter compounds may not be present in this strain. The strain did not reduce other GIT-related reactive compounds, including acrylamide, glyoxal, and furan.

Arabidopsis At5g39790 encodes a chloroplast-localized, carbohydrate-binding, coiled-coil domain-containing putative scaffold protein.

BACKGROUND: Starch accumulation and degradation in chloroplasts is accomplished by a suite of over 30 enzymes. Recent work has emphasized the importance of multi-protein complexes amongst the metabolic enzymes, and the action of associated non-enzymatic regulatory proteins. Arabidopsis At5g39790 encodes a protein of unknown function whose sequence was previously demonstrated to contain a putative carbohydrate-binding domain. RESULTS: We here show that At5g39790 is chloroplast-localized, and binds starch, with a preference for amylose. The protein persists in starch binding under conditions of pH, redox and Mg(+2) concentrations characteristic of both the day and night chloroplast cycles. Bioinformatic analysis demonstrates a diurnal pattern of gene expression, with an accumulation of transcript during the light cycle and decline during the dark cycle. A corresponding diurnal pattern of change in protein levels in leaves is also observed. Sequence analysis shows that At5g39790 has a strongly-predicted coiled-coil domain. Similar analysis of the set of starch metabolic enzymes shows that several have strong to moderate coiled-coil potential. Gene expression analysis shows strongly correlated patterns of co-expression between At5g39790 and several starch metabolic enzymes. CONCLUSION: We propose that At5g39790 is a regulatory scaffold protein, persistently binding the starch granule, where it is positioned to interact by its coiled-coil domain with several potential starch metabolic enzyme binding-partners.

The PII signal transduction protein of Arabidopsis thaliana forms an arginine-regulated complex with plastid N-acetyl glutamate kinase.

The PII proteins are key mediators of the cellular response to carbon and nitrogen status and are found in all domains of life. In eukaryotes, PII has only been identified in red algae and plants, and in these organisms, PII localizes to the plastid. PII proteins perform their role by assessing cellular carbon, nitrogen, and energy status and conferring this information to other proteins through protein-protein interaction. We have used affinity chromatography and mass spectrometry to identify the PII-binding proteins of Arabidopsis thaliana. The major PII-interacting protein is the chloroplast-localized enzyme N-acetyl glutamate kinase, which catalyzes the key regulatory step in the pathway to arginine biosynthesis. The interaction of PII with N-acetyl glutamate kinase was confirmed through pull-down, gel filtration, and isothermal titration calorimetry experiments, and binding was shown to be enhanced in the presence of the downstream product, arginine. Enzyme kinetic analysis showed that PII increases N-acetyl glutamate kinase activity slightly, but the primary function of binding is to relieve inhibition of enzyme activity by the pathway product, arginine. Knowing the identity of PII-binding proteins across a spectrum of photosynthetic and non-photosynthetic organisms provides a framework for a more complete understanding of the function of this highly conserved signaling protein.

N-acetyl glutamate kinase from Daucus carota suspension cultures: embryogenic expression profile, purification and characterization.

In Daucus carota, N-acetylglutamate-5-phosphotransferase (NAGK; E.C. 2.7.2.8) specific activity was shown to correlate with the progression of somatic embryogenesis and was highest in the latter stages, where growth was most rapid. The enzyme was subsequently purified greater than 1200-fold using heat treatment, ammonium sulfate fractionation, gel filtration, anion exchange and dye ligand chromatography. Carrot NAGK was shown to have a subunit molecular weight of 31 kDa and form a hexamer. The Kms for NAG and ATP are 5.24 and 2.11 mM, respectively. Arginine (Arg) is a K-type allosteric inhibitor of the enzyme, and Hill coefficients in the order of 5 in the presence of Arg suggest that the enzyme is highly cooperative. D. carota NAGK does not bind to Arabidopsis thaliana PII affinity columns, nor does the A. thaliana PII increase NAGK specific activity, indicating its cellular location is probably different.

In vivo 31P nuclear magnetic resonance investigation of tellurite toxicity in Escherichia coli.

Here we compare the physiological state of Escherichia coli exposed to tellurite or selenite by using the noninvasive technique of phosphorus-31 nuclear magnetic resonance (NMR) spectroscopy. We studied glucose-fed Escherichia coli HB101 cells containing either a normal pUC8 plasmid with no tellurite resistance determinants present or the pTWT100 plasmid which contains the resistance determinants tehAB. No differences could be observed in intracellular ATP levels, the presence or absence of a transmembrane pH gradient, or the levels of phosphorylated glycolytic intermediates when resistant cells were studied by 31P NMR in the presence or absence of tellurite. In the sensitive strain, we observed that the transmembrane pH gradient was dissipated and intracellular ATP levels were rapidly depleted upon exposure to tellurite. Only the level of phosphorylated glycolytic intermediates remained the same as observed with resistant cells. Upon exposure to selenite, no differences could be observed by 31P NMR between resistant and sensitive strains, suggesting that the routes for selenite and tellurite reduction within the cells differ significantly, since only tellurite is able to collapse the transmembrane pH gradient and lower ATP levels in sensitive cells. The presence of the resistance determinant tehAB, by an as yet unidentified detoxification event, protects the cells from uncoupling by tellurite.

Using cytochome c to monitor electron transport and inhibition in beef heart submitochondrial particles*.

We present a two-part undergraduate laboratory exercise. In the first part, electron transport in bovine heart submitochondrial particles causing reduction of cytochrome c is monitored at 550 nm. Redox-active dyes have historically been used in most previous undergraduate laboratory exercises of this sort but do not demonstrate respiratory inhibition by antimycin A and rotenone. By using cytochrome c instead of redox-active dyes, it is possible to observe inhibition of electron transport in the presence of the aforementioned respiratory inhibitors. In the second part, students are asked to design a soluble redox chain between NADH and cytochrome c using catalytic amounts of redox-active dyes. The students are also responsible for designing the assays and control. The entire experiment can be performed in 3 h with single-beam spectrophotometers that are currently used in most undergraduate teaching laboratories. This exercise is suitable for large undergraduate classes of over 200 students and can be performed either by a single student or a student pair.

Towards a structure-function analysis of bovine lactoferricin and related tryptophan- and arginine-containing peptides.

The iron-binding protein lactoferrin is a multifunctional protein that has antibacterial, antifungal, antiviral, antitumour, anti-inflammatory, and immunoregulatory properties. All of these additional properties appear to be related to its highly basic N-terminal region. This part of the protein can be released in the stomach by pepsin cleavage at acid pH. The 25-residue antimicrobial peptide that is released is called lactoferricin. In this work, we review our knowledge about the structure of the peptide and attempt to relate this to its many functions. Microcalorimetry and fluorescence spectroscopy data regarding the interaction of the peptide with model membranes show that binding to net negatively charged bacterial and cancer cell membranes is preferred over neutral eukaryotic membranes. Binding of the peptide destabilizes the regular membrane bilayer structure. Residues that are of particular importance for the activity of lactoferricin are tryptophan and arginine. These two amino acids are also prevalent in "penetratins", which are regions of proteins or synthetic peptides that can spontaneously cross membranes and in short hexapeptide antimicrobial peptides derived through combinatorial chemistry. While the antimicrobial, antifungal, antitumour, and antiviral properties of lactoferricin can be related to the Trp/Arg-rich portion of the peptide, we suggest that the anti-inflammatory and immunomodulating properties are more related to a positively charged region of the molecule, which, like the alpha- and beta-defensins, may act as a chemokine. Few small peptides are involved in as wide a range of host defense functions as bovine and human lactoferricin.