Isolation and characterization of cDNA clones for α- and β-subunits of ovine luteinizing hormone

A cDNA library of ovine pituitary DNA in plasmid pBR322 has been constructed by conventional methods with certain modifications. The library was screened using partial cDNAs for ratα-subunit and LHβ. We have isolated cDNA clones for ovineα-subunit and LHβ. The identification of these clones was confirmed by partial sequencing. The clones bear about 80% sequence homology with the respective rat cDNAs in the sequenced regions and hybridize with the rat clones in 5 X SSC at 55°C. The ovine LHβ clone has an insert of about 650 bp and selects an RNA of about 750 bases in a northern blot. The α-subunit cDNA clone has an insert of about 550 bp; it has two internalPst I sites and thus shows restriction-based differences from ratα-subunit cDNA, which does not have anyPst I site.     

Characterization of glycerol dehydratase expressed by fusing its α- and β-subunits

The gdh and gdhr genes, encoding B₁₂-dependent glycerol dehydratase (GDH) and glycerol dehydratase reactivase (GDHR), respectively, in Klebsiella pneumoniae, were cloned and expressed in E. coli. Part of the β-subunit was lost during GDH purification when co-expressing α, β and γ subunit. This was overcome by fusing the β-subunit to α- or γ-subunit with/without the insertion of a linker peptide between the fusion moieties. The kinetic properties of the fusion enzymes were characterized and compared with wild type enzyme. The results demonstrated that the fusion protein GDHALB/C, constructed by linking the N-terminal of β-subunit to the C-terminal of α subunit through a (Gly₄Ser)₄ linker peptide, had the greatest catalytic activity. Similar to the wild-type enzyme, GDHALB/C underwent mechanism-based inactivation by glycerol during catalysis and could be reactivated by GDHR. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Suppression of β-oxidation restores pyruvate inhibition of pyruvate dehydrogenase kinase in starved rat heart

Kinetic behaviour of rat heart pyruvate dehydrogenase kinase (PDHK) was studied in the multi-enzyme complex (PDC) contained in two preparations: mitochondria (mPDC) and a high speed pellet of Triton-extracted tissue (hPDC). Two parameters were evaluated: Va_av, related to V_max, and Fractional Pyruvate Inhibition (FPI). Starvation of rats for 48 h led to a rise in V_av and a fall in FPI. Injection into starved rats of agents which reduce -oxidation of fatty acids restored, in succession, FPI and then V_av, of hPDC, to levels found in hPDC from fed animals. In vitro incubation at 30°C of hPDC from starved animals restored FPI, but not V_av, to fed values; both were restored during in vitro incubation of mPDC from starved animals within the same time frame as in the in vivo experiments. A sharp increase of FPI, but not V_av, of hPDC from both fed and starved rats was observed in later experiments. This could have been due to differential selection of the two genes for isoenzymes of PDHKa proposed by other workers.     

Accumulation of β-conglycinin in soybean cotyledon through the formation of disulfide bonds between α'- and α-subunits

β-Conglycinin, one of the major soybean (Glycine max) seed storage proteins, is folded and assembled into trimers in the endoplasmic reticulum and accumulated into protein storage vacuoles. Prior experiments have used soybean β-conglycinin extracted using a reducing buffer containing a sulfhydryl reductant such as 2-mercaptoethanol, which reduces both intermolecular and intramolecular disulfide bonds within the proteins. In this study, soybean proteins were extracted from the cotyledons of immature seeds or dry beans under nonreducing conditions to prevent the oxidation of thiol groups and the reduction or exchange of disulfide bonds. We found that approximately half of the α'- and α-subunits of β-conglycinin were disulfide linked, together or with P34, prior to amino-terminal propeptide processing. Sedimentation velocity experiments, size-exclusion chromatography, and two-dimensional polyacrylamide gel electrophoresis (PAGE) analysis, with blue native PAGE followed by sodium dodecyl sulfate-PAGE, indicated that the β-conglycinin complexes containing the disulfide-linked α'/α-subunits were complexes of more than 720 kD. The α'- and α-subunits, when disulfide linked with P34, were mostly present in approximately 480-kD complexes (hexamers) at low ionic strength. Our results suggest that disulfide bonds are formed between α'/α-subunits residing in different β-conglycinin hexamers, but the binding of P34 to α'- and α-subunits reduces the linkage between β-conglycinin hexamers. Finally, a subset of glycinin was shown to exist as noncovalently associated complexes larger than hexamers when β-conglycinin was expressed under nonreducing conditions.     

Association of α-subunits with nucleotide-modified β-subunits induces asymmetry in the catalytic sites of the F1-ATPase α3β3

The photoaffinity spin-labeled ATP analog, 2-N₃-SL-adenosine triphosphate (ATP), was used to covalently modify isolated β-subunits from F₁-ATPase of the thermophilic bacterium PS3. Approximately 1.2 mol of the nucleotide analog bound to the isolated subunit in the dark. Irradiation leads to covalent incorporation of the nucleotide into the binding site. ESR spectra of the complex show a signal that is typical for protein-immobilized radicals. Addition of isolated α-subunits to the modified β-subunits results in ESR spectra with two new signals indicative of two distinctly different environments of the spin-label, e.g., two distinctly different conformations of the catalytic sites. The relative ratio of the signals is approx 2∶1 in favor of the more closed conformation. The data show for the first time that when nucleotides are bound to isolated β-subunits, binding of α-subunits induces asymmetry in the catalytic sites even in the absence of the γ-subunit. This work was supported by a grant from the Deutsche Forschungsgemeinschaft to PDV.     

Characterization of the mRNAs for α-, β- and γ-actin

The mRNAs for α-, β- and γ-actin have been characterized with respect to molecular weight and poly(A) content. Polyacrylamide gel electrophoresis under denaturing conditions shows that the mRNA for α-actin (muscle-specific actin) is approximately 4.6 × 10⁵ daltons in size, and that the mRNAs for β- and γ-actin (nonmuscle actins) are much larger, approximately 6.6 × 10⁵ daltons in size. We therefore calculate that the noncoding regions of the β- and γ-actin mRNAs contain about 800 nucleotides. This is in marked contrast to the noncoding regions of α-actin mRNA which contain only about 180 nucleotides. During electrophoresis in high-resolution nondenaturing gels, the β-actin mRNA migrates slightly slower than the γ-actin mRNA. This indicates either that β-actin mRNA is about 100 nucleotides longer than γ-actin mRNA, or that these mRNAs differ in secondary structure. Fractionation of actin mRNA on the basis of poly(A) content shows that a substantial portion of the β-actin mRNA, but very little of the α- or γ-actin mRNAs, fails to bind to oligo(dT)-cellulose. Much of this poly(A)-deficient β-actin mRNA, however, does bind to poly(U)-Sepharose, a substrate with higher affinity for short poly(A) sequences. This indicates that many of these β-actin mRNA molecules are polyadenylated, but that they have unusually short poly(A) tails. The finding that β- and γ-actins are translated from mRNAs of different electrophoretic mobility and different poly(A) content strongly suggests that these two closely related proteins are products of different genes.     

A PCR-based method to test for the presence or absence of β-conglycinin α′- and α-subunits in soybean

The soybean cultivar Yumeminori, which lacks the α′- and α-subunits of β-conglycinin, carries both naturally occurring and induced mutations. While the cause of the natural mutation resulting in the α′-subunit deficiency has been determined, the induced mutation in the CG-2 gene encoding the α-subunit has not been characterized at the molecular level. In this study, we identified a four base pair insertion in the first exon of CG-2, which introduced a premature stop codon. The insertion co-segregated with the lack of α-subunit, indicating that this mutation is the cause of the α-subunit deficiency. A multiplex PCR method of testing for the presence or absence of α′- and α-subunits was developed based on the sequences of mutated and wild-type alleles. This PCR-based test was also capable of detecting the presence of wild-type genes when Yumeminori DNA samples were contaminated with wild-type DNA at levels of 0.2% or greater. Thus, this method will be useful both for marker-assisted selection in soybean breeding programs, and for seed purity tests in food industries.     

Properties of allophycocyanin II and its α- and β-subunits from the thermophilic blue–green alga Mastigocladus laminosus

Purified allophycocyanin II and its subunits have been examined with respect to spectroscopic properties, sedimentation, reconstitution and isoelectric behaviour. In 0.02m-potassium phosphate buffer, pH8.0, and at a concentration of 0.25mg/ml, allophycocyanin II and its alpha- and beta-subunits show visible absorption maxima at 650, 615 and 615nm respectively, whereas the fluorescence emission maxima were determined to be at 662, 640 and 630nm respectively. The absorption difference spectrum (dilution difference) of allophycocyanin II displays maxima at 650 and 590nm with a minimum at 610nm. The c.d. spectrum of allophycocyanin II showed only one positive-ellipticity band at 635nm, and a major negative-ellipticity band at 340nm. Oxidation of allophycocyanin II, low- and high-pH solutions (pH3.0 and 11.0), various ethanol concentrations as well as dialysis against distilled water induce a spectral change leading to phycocyanin-like characteristics. In most cases these shifts are reversible. Allophycocyanin II is thermostable over a period of 60min at temperatures up to 60 degrees C. The isoelectric points of allophycocyanin II and its alpha- and beta-subunits are 4.65, 4.64 and 4.82 respectively. Estimated molecular weights from sedimentation-equilibrium analyses were 102500 for allophycocycanin II, 16000 for the alpha- and 31500 for the beta-subunit. Recombination of alpha- and beta-subunits leads to allophycocyanin II, which is indistinguishable from native allophycocyanin with respect to its spectral form, to its gel-filtration and to its electrophoretic behaviour.     

Characterization of the α- and β-Mannosidases of Porphyromonas gingivalis

Mannose is an important sugar in the biology of the Gram-negative bacterium Porphyromonas gingivalis. It is a major component of the oligosaccharides attached to the Arg-gingipain cysteine proteases, the repeating units of an acidic lipopolysaccharide (A-LPS), and the core regions of both types of LPS produced by the organism (O-LPS and A-LPS) and a reported extracellular polysaccharide (EPS) isolated from spent culture medium. The organism occurs at inflamed sites in periodontal tissues, where it is exposed to host glycoproteins rich in mannose, which may be substrates for the acquisition of mannose by P. gingivalis. Five potential mannosidases were identified in the P. gingivalis W83 genome that may play a role in mannose acquisition. Four mannosidases were characterized in this study: PG0032 was a β-mannosidase, whereas PG0902 and PG1712 were capable of hydrolyzing p-nitrophenyl α-d-mannopyranoside. PG1711 and PG1712 were α-1→3 and α-1→2 mannosidases, respectively. No enzyme function could be assigned to PG0973. α-1→6 mannobiose was not hydrolyzed by P. gingivalis W50. EPS present in the culture supernatant was shown to be identical to yeast mannan and a component of the medium used for culturing P. gingivalis and was resistant to hydrolysis by mannosidases. Synthesis of O-LPS and A-LPS and glycosylation of the gingipains appeared to be unaffected in all mutants. Thus, α- and β-mannosidases of P. gingivalis are not involved in the harnessing of mannan/mannose from the growth medium for these biosynthetic processes. P. gingivalis grown in chemically defined medium devoid of carbohydrate showed reduced α-mannosidase activity (25%), suggesting these enzymes are environmentally regulated.     

Conformational stabilities of the rat α- and β-parvalbumins

It is widely believed that β-parvalbumin (PV) isoforms are intrinsically less stable than α-parvalbumins, due to greater electrostatic repulsion and an abbreviated C-terminal helix. However, when examined by differential scanning calorimetry, the apo-form of the rat β-PV (i.e. oncomodulin) actually displays greater thermal stability than the α-PV. Whereas the melting temperature of the α isoform is 45.8°C at physiological pH and ionic strength, the T_m for the β isoform is more than 7° higher (53.6°C). This result suggests that factors besides net charge and C-terminal helix length strongly influence parvalbumin conformational stability. Extension of the F helix in the β-PV, by insertion of Ser-109, has a modest stabilizing effect, raising the T_m by 1.1°. Truncation of the α-PV F helix, by removal of Glu-108, has a more profound impact, lowering the T_m by 4.0°.     

The effect of acetate on the regulation of the branched chain α-keto acid and the pyruvate dehydrogenase complexes in the perfused rat liver

The regulatory consequences of acetate infusion on the pyruvate and the branched chain α-keto acid dehydrogenase reactions in the isolated, perfused rat liver were investigated. Metabolic flux through these two decarboxylation reactions was monitored by measuring the rate of ¹⁴CO₂ production from infused 1-¹⁴C-labeled substrates. When acetate was presented to the liver as the sole substrate the rate of ketogenesis which resulted was maximal at concentrations of acetate in excess of 10 mm. The increase in hepatic ketogenesis during acetate infusion was not accompanied by an alteration of the mitochondrial oxidation-reduction state as measured by the ratio of β-hydroxybutyrate/ acetoacetate in the effluent perfusate. While acetate infusion did not affect the rate of α-keto[1-¹⁴C]isocaproate decarboxylation, the rate of α-keto[1-¹⁴C]isovalerate decarboxylation was stimulated appreciably upon acetate addition. No change was observed in the amount of extractable branched chain α-keto acid dehydrogenase during acetate infusion. The rate of [1-¹⁴C]pyruvate decarboxylation was stimulated in the presence of acetate at low (<1 mm) but not at high (>1 mm) perfusate pyruvate concentrations. The stimulation of the metabolic flux through the pyruvate dehydrogenase reaction upon acetate infusion was accompanied by an increase in the activation state of the pyruvate dehydrogenase complex from 25.7 to 35.6% in the active form. In a liver perfused in the presence of the pyruvate dehydrogenase kinase inhibitor, dichloroacetate, at a low concentration of pyruvate (0.05 mm) the infusion of acetate did not affect the rate of pyruvate decarboxylation. As the rate of mitochondrial acetoacetate efflux is increased during acetate infusion the stimulation of pyruvate and α-ketoisovalerate decarboxylation is attributed to an accelerated rate of exchange of mitochondrial acetoacetate for cytosolic pyruvate or α-ketoisovalerate on the monocarboxylate transporter.     

Differences between α- and β-Chain Mutants of Human Haemoglobin and between α- and β-Thalassaemia. Possible Duplication of the α-Chain Gene

Human adult haemoglobin consists of two unlike pairs of polypeptide chains, and can be described as α₂β₂. Amino-acid substitutions in either of the two types of chain result in α- and β-chain variants. In thalassaemia, which causes a lowered production of haemoglobin, the α or the β chain can be affected, the result being α- or β-thalassaemia. There is a quantitative difference in the proportion of α- and β-chain variants to normal haemoglobin in the respective heterozygotes, and there is also a difference in the pattern of inheritance of α- and β-thalassaemia: these could possibly be explained by assuming that man has one gene for the β- and two for the α-chain.     

The isolation and amino acid sequence of the β- and γ-subunits of the lectin from the seeds of Dioclea Grandiflora

Although the two smaller β- and γ- subunits of the lectin from Dioclea grandiflora were clearly resolved by sodium dodecyl sulphate (SDS) gel electrophoresis, the concensus of other techniques including ultracentrifugation, isoelectric focusing in 8 M urea, size-exclusion chromatography in dissociating solvents and amino acid and sequence analysis indicated that they were similar in molecular size and that they had arisen either by a single enzymic cleavage at Asn¹¹⁸-Ser¹¹⁹ in the middle of the 237 residue-long mature α-subunit or by multiple cleavages occurring during post-translational processing of intermediates. The existence of minor forms of the β- and γ- subunits resulting from a cleavage at Asn¹²⁴-Ser¹²⁵ of the α-subunit was also recognized. The results indicated that the apparent difference in molecular size of the β- and γ-subunits deduced from SDS-gel electrophoresis could be explained by the anomalous behaviour of both subunits in this separation technique. The structural features of the D. grandiflora lectin are compared with those of concanavalin A obtained from seeds of the botanically related Canavalia ensiformis.     

Amino acid sequences of allophycocyanin α- and β-subunits isolated from Anabaena cylindrica: Presence of an unknown derivative of aspartic acid in the β-subunit

Allophycocyanin (APC) α- and β-subunits were isolated from Anabaena cylindrica and their amino acid sequences were determined. The α- and β-subunits consisted of 160 and 161 amino acid residues, respectively, and lacked tryptophan. The β-subunit contained an unknown derivative of aspartic acid. The sequences were compared with those of other allophycocyanins.     

Inactivation and reactivation of the mitochondrial α-ketoglutarate dehydrogenase complex

Reduced brain metabolism is an invariant feature of Alzheimer Disease (AD) that is highly correlated to the decline in brain functions. Decreased activities of key tricarboxylic acid cycle (TCA) cycle enzymes may underlie this abnormality and are highly correlated to the clinical state of the patient. The activity of the α-ketoglutarate dehydrogenase complex (KGDHC), an arguably rate-limiting enzyme of the TCA cycle, declines with AD, but the mechanism of inactivation and whether it can be reversed remains unknown. KGDHC consists of multiple copies of three subunits. KGDHC is sensitive to oxidative stress, which is pervasive in AD brain. The present studies tested the mechanism for the peroxynitrite-induced inactivation and subsequent reactivation of purified and cellular KGDHC. Peroxynitrite inhibited purified KGDHC activity in a dose-dependent manner and reduced subunit immunoreactivity and increased nitrotyrosine immunoreactivity. Nano-LC-MS/MS showed that the inactivation was related to nitration of specific tyrosine residues in the three subunits. GSH diminished the nitrotyrosine immunoreactivity of peroxynitrite-treated KGDHC, restored the activity and the immunoreactivity for KGDHC. Nano-LC-MS/MS showed this was related to de-nitration of specific tyrosine residues, suggesting KGDHC may have a denitrase activity. Treatment of N2a cells with peroxynitrite for 5 min followed by recovery of cells for 24 h reduced KGDHC activity and increased nitrotyrosine immunoreactivity. Increasing cellular GSH in peroxynitrite-treated cells rescued KGDHC activity to the control level. The results suggest that restoring KGDHC activity is possible and may be a useful therapeutic approach in neurodegenerative diseases.     

Effects of pyruvate dehydrogenase subunits overexpression on the α-ketoglutarate production in Yarrowia lipolytica WSH-Z06

Yarrowia lipolytica WSH-Z06 harbours a promising capability to oversynthesize α-ketoglutarate (α-KG). Its wide utilization is hampered by the formation of high concentrations of pyruvate. In this study, a metabolic strategy for the overexpression of the α and β subunits of pyruvate dehydrogenase E1, E2 and E3 components was designed to reduce the accumulation of pyruvate. Elevated expression level of α subunit of E1 component improved the α-KG production and reduced the pyruvate accumulation. Due to a reduction in the acetyl-CoA supply, neither the growth of cells nor the synthesis of α-KG was restrained by the overexpression of β subunit of E1, E2 and E3 components. Furthermore, via the overexpression of these thiamine pyrophosphate (TPP)-binding subunits, the dependency of pyruvate dehydrogenase on thiamine was diminished in strains T1 and T2, in which α and β subunits of E1 component were separately overexpressed. In these two recombinant strains, the accumulation of pyruvate was insensitive to variations in exogenous thiamine. The results suggest that α-KG production can be enhanced by altering the dependence on TPP of pyruvate dehydrogenase and that the competition for the cofactor can be switched to ketoglutarate dehydrogenase via separate overexpression of the TPP-binding subunits of pyruvate dehydrogenase. The results presented here provided new clue to improve α-KG production.     

Investigation of Intramolecular Dynamics and Conformations of α-, β- and γ-Synuclein

The synucleins are a family of natively unstructured proteins consisting of α-, β-, and γ-synuclein which are primarily expressed in neurons. They have been linked to a wide variety of pathologies, including neurological disorders, such as Parkinson’s disease (α-synuclein) and dementia with Lewy bodies (α- and β-synuclein), as well as various types of cancers (γ-synuclein). Self-association is a key pathological feature of many of these disorders, with α-synuclein having the highest propensity to form aggregates, while β-synuclein is the least prone. Here, we used a combination of fluorescence correlation spectroscopy and single molecule Förster resonance energy transfer to compare the intrinsic dynamics of different regions of all three synuclein proteins to investigate any correlation with putative functional or dysfunctional interactions. Despite a relatively high degree of sequence homology, we find that individual regions sample a broad range of diffusion coefficients, differing by almost a factor of four. At low pH, a condition that accelerates aggregation of α-synuclein, on average smaller diffusion coefficients are measured, supporting a hypothesis that slower intrachain dynamics may be correlated with self-association. Moreover, there is a surprising inverse correlation between dynamics and bulkiness of the segments. Aside from this observation, we could not discern any clear relationship between the physico-chemical properties of the constructs and their intrinsic dynamics. This work suggests that while protein dynamics may play a role in modulating self-association or interactions with other binding partners, other factors, particularly the local cellular environment, may be more important.