Characterization of a murine type IIB procollagen-specific antibody

Type II collagen is the major collagenous component of the cartilage extracellular matrix; formation of a covalently cross-linked type II collagen network provides cartilage with important tensile properties. The Col2a1 gene is encoded by 54 exons, of which exon 2 is subject to alternative splicing, resulting in different isoforms named IIA, IIB, IIC and IID. The two major procollagen protein isoforms are type IIA and type IIB procollagen. Type IIA procollagen mRNA contains exon 2 and is generated predominantly by chondroprogenitor cells and other non-cartilaginous tissues. Differentiated chondrocytes generate type IIB procollagen, devoid of exon 2. Although type IIA procollagen is produced in certain non-collagenous tissues during development, this developmentally-regulated alternative splicing switch to type IIB procollagen is restricted to cartilage cells. Though a much studied and characterized molecule, the importance of the various type II collagen protein isoforms in cartilage development and homeostasis is still not completely understood. Effective antibodies against specific epitopes of these isoforms can be useful tools to decipher function. However, most type II collagen antibodies to date recognize either all isoforms or the IIA procollagen isoform. To specifically identify the murine type IIB procollagen, we have generated a rabbit antibody (termed IIBN) directed to a peptide sequence that spans the murine exon 1–3 peptide junction. Characterization of the affinity-purified antibody by western blotting of collagens extracted from wild type murine cartilage or cartilage from Col2a1^+ ex2 knock-in mice (which generates predominantly the type IIA procollagen isoform) demonstrated that the IIBN antibody is specific to the type IIB procollagen isoform. IIBN antibody was also able to detect the native type IIB procollagen in the hypertrophic chondrocytes of the wild type growth plate, but not in those of the Col2a1^+ ex2 homozygous knock-in mice, by both immunofluorescence and immunohistochemical studies. Thus the IIBN antibody will permit an in-depth characterization of the distribution of IIB procollagen isoform in mouse skeletal tissues. In addition, this antibody will be an important reagent for characterizing mutant type II collagen phenotypes and for monitoring type II procollagen processing and trafficking.     

Effects of maturation and co-culture treatments on the developmental capacity of early bovine embryos.

A total of 901 cumulus-oocyte complexes (COCs) were collected from bovine ovaries obtained at a local abattoir. COCs randomly assigned to Treatment I (n = 451), were cultured in TCM-199 + 10% fetal bovine serum (FBS) and hormones, while oocytes in Treatment II (n = 450) were cultured in TCM-199 + 20% estrous cow serum (ECS). Assessment of maturation revealed that 91.3% (42/46) of oocytes in Treatment I had reached metaphase II of meiosis, which was greater (P less than 0.05) than the 73.3% (33/45) in Treatment II. Following in vitro fertilization, 203 oocytes from Treatment I were co-cultured on bovine granulosa cells (Treatment IA) while the remaining 202 oocytes were co-cultured on bovine oviductal cells (Treatment IB). Similarly, 203 oocytes from Treatment II were co-cultured on granulosa cells (Treatment IIA) or oviductal cells (Treatment IIB, n = 202). Co-culture was maintained for 8 days. The proportion of cleaved zygotes was higher (P less than 0.05) in Treatment IB (86.6%) compared to Treatments IA (78.8%), IIA (58.1%), and IIB (64.8%). The proportion of cleaved zygotes that progressed beyond the 16-cell stage was also greater (P less than 0.001) in Treatment IB (71.4%) compared to Treatments IA (50.0%), IIA (35.4%) and IIB (55.8%). Treatment IB also produced the highest proportion of blastocysts (P less than 0.0001) (41.1%) versus 24.6% (IA), 11.3% (IIA) and 18.3% (IIB). The proportion of day 6 morulae that progressed to form day 8 blastocysts was similar for both co-culture treatments (IA, 70.1%; IB 70.2%; IIA, 51.5%; IIB 50.8%) and varied only between in vitro maturation groups.(ABSTRACT TRUNCATED AT 250 WORDS)     

Potentiality of Azolla as a suitable P-biofertilizer under salinity through acid phosphatase activity

The cellular and extracellular acid phosphatase (APase, Electrical Conductivity (EC) 3.1.3.2) activities in different Azolla spp. were induced in P-deprived condition after 48 h and maximum was on the 12th day of incubation. APase activity has been investigated at different levels of NaCl. Highest cellular and extracellular APase activities were observed in A. microphylla at 20 (2-fold of the control) and 30 mM (3.2-fold of the control) NaCl, respectively, while lowest were in A. filiculoides. Presence of different concentrations of micro- and macronutrients in saline medium regulated the APase activity of the Azolla. Ca²⁺ played a major role in enhancing the APase activity under salinity. Heavy metals did not affect APase activity at the lower level, whereas its higher level inhibited the activity. The enhancement in the APase activity under moderate salinity suggests the major contribution of APase activity during salt-responsive physiological adaptation of Azolla possibly by providing maximum inorganic phosphate to the association, which might be helpful in compensating for the energy crisis caused by salt-induced inhibition in photosynthetic machinery and also in regulating the nutrient imbalances during salt shock or process of adaptation towards heavily polluted agricultural land.     

The white-rot fungus Cerrena unicolor strain 137 produces two laccase isoforms with different physico-chemical and catalytic properties

Cerrena unicolor secreted two laccase isoforms with different characteristics during the growth in liquid media. In a synthetic low-nutrient nitrogen glucose medium (Kirk medium), high amounts of laccase (4,000 U l⁻¹) were produced in response to Cu²⁺. Highest laccase levels (19,000 U l⁻¹) were obtained in a complex tomato juice medium. The isoforms (Lacc I, Lacc II) were purified to homogeneity with an overall yield of 22%. Purification involved ultrafiltration and Mono Q separation. Lacc I and II had M _w of 64 and 57 kDa and pI of 3.6 and 3.7, respectively. Both isoforms had an absorption maximum at 608 nm but different pH optima and thermal stability. Optimum pH ranged from 2.5 to 5.5 depending on the substrate. The pH optima of Lacc II were always higher than those of Lacc I. Both laccases were stable at pH 7 and 10 but rapidly lost activity at pH 3. Their temperature optimum was around 60°C, and at 5°C they still reached 30% of the maximum activity. Lacc II was the more thermostable isoform that did not lose any activity during 6 months storage at 4°C. Kinetic constants (K _m, k _cat) were determined for 2,2′-azino-bis(3-ethylthiazoline-6-sulfonate) (ABTS), 2,6-dimethoxyphenol and syringaldazine.     

Unusual hepatic mitochondrial arginase in an Indian air-breathing teleost,Heteropneustes fossilis: Purification and characterization

A functional urea cycle with both cytosolic (ARG I) and mitochondrial (ARG II) arginase activity is present in the liver of an ureogenic air-breathing teleost, Heteropneustes fossilis. Antibodies against mammalian ARG II showed no cross-reactivity with the H. fossilis ARG II. ARG II was purified to homogeneity from H. fossilis liver. Purified ARG II showed a native molecular mass of 96 kDa. SDS–PAGE showed a major band at 48 kDa. The native enzyme, therefore, appears to be a homodimer. The pI value of the enzyme was 7.5. The purified enzyme showed maximum activity at pH 10.5 and 55 °C. The K_m of purified ARG II for l-arginine was 5.25 ± 1.12 mM. l-Ornithine and N^ω-hydroxy-l-arginine showed mixed inhibition with K_i values 2.16 ± 0.08 and 0.02 ± 0.004 mM respectively. Mn^+ 2 and Co^+ 2 were effective activators of arginase activity. Antibody raised against purified H. fossilis ARG II did not cross-react with fish ARG I, and mammalian ARG I and ARG II. Western blot with the antibodies against purified H. fossilis hepatic ARG II showed cross reactivity with a 96 kDa band on native PAGE and a 48 kDa band on SDS–PAGE. The molecular, immunological and kinetic properties suggest uniqueness of the hepatic mitochondrial ARG II in H. fossilis.     

Receptor properties of corticosteroid binder IB

Corticosteroid binder IB, present in liver and kidney, is pronounced in liver cytosol after injection of [³H]triamcinolone acetonide. Following injection of the radioactive ligand, livers homogenized in the presence of 20 mm molybdate, 2 mm leupeptin hemisulfate, 2 mm antipain, or 2 mm phenylmethylsufonyl fluoride produce cytosols with Chromatographie profiles of binders II and IB identical to controls, as determined by DEAE-Sephadex chromatography, suggesting that IB is a cellular constituent rather than a product of protease action (sensitive to the above inhibitors) after cell breakage. Generation of IB in kidney cytosols in vitro appears to be unrelated to protease activity. Liver binder IB has an S value of 5–6 and a Stokes radius of about 26 Å producing a calculated range of molecular weight from 40,000 to 50,000 with frictional coefficient and axial ratio close to spherical values. As expected of a steroid receptor, IB, like II, binds to DNA and to liver cell nuclei but IB binds more tightly as evidenced by the fact that KCl is more effective in eluting II than IB from nuclei. Because recovery of bound radioactivity from acceptors is sometimes difficult to achieve, indirect experiments have been used frequently to determine the binding. Pyridoxal phosphate extracts liver IB and II equally from nuclei but spermidine is ineffective. While IB and II can be extracted partially from nuclei by pancreatic DNase I, more binder II is extracted by this method than IB. Micrococcal nuclease is poorly effective in either case. Binder II is extracted to a greater degree from DNA-cellulose than is IB by spermidine, MgCl₂, pyridoxal phosphate, and NaCl. IB binds more extensively to homodeoxypolymers than II. The extent of binding of liver IB to homodeoxypolymers is in the order: poly(dC) ≥ poly(dG) > poly(dA) ? poly(dT), whereas the order for liver binder II is: poly(dG) ≥ poly(dT) > poly(dC) ? poly(dA). Binders IB and II may be separate gene products or IB may arise in the cell from post-translational action. In the latter case, the activity of a protease cannot be ruled out.     

Paraoxon, 4-nitrophenyl phosphate and acetate are substrates of α- but not of β-, γ- and ζ-carbonic anhydrases

Carbonic anhydrases (CAs, EC 4.2.1.1) belonging to α-, β-, γ- and ζ-classes and from various organisms, ranging from the bacteria, archaea to eukarya domains, were investigated for their esterase/phosphatase activity with 4-nitrophenyl acetate, 4-nitrophenyl phosphate and paraoxon as substrates. Only α-CAs showed esterase/phosphatase activity, whereas enzymes belonging to the β-, γ- and ζ-classes were completely devoid of such activity. Paraoxon, the metabolite of the organophosphorus insecticide parathione, was a much better substrate for several human/murine α-CA isoforms (CA I, II and XIII), with k_cat/K_M in the range of 2681.6–4474.9 M^?1 s^?1, compared to 4-nitrophenyl phosphate (k_cat/K_M of 14.9–1374.4 M^?1 s^?1).     

Functional divergence of human cytoplasmic myosin II: kinetic characterization of the non-muscle IIA isoform

Cytoplasmic (or non-muscle) myosin II isoforms are widely expressed molecular motors playing essential cellular roles in cytokinesis and cortical tension maintenance. Two of the three human non-muscle myosin II isoforms (IIA and IIB) have been investigated at the protein level. Transient kinetics of non-muscle myosin IIB showed that this motor has a very high actomyosin ADP affinity and slow ADP release. Here we report the kinetic characterization of the non-muscle myosin IIA isoform. Similar to non-muscle myosin IIB, non-muscle myosin IIA shows high ADP affinity and little enhancement of the ADP release rate by actin. The ADP release rate constant, however, is more than an order of magnitude higher than the steady-state ATPase rate. This implies that non-muscle myosin IIA spends only a small fraction of its ATPase cycle time in strongly actin-bound states, which is in contrast to non-muscle myosin IIB. Non-muscle myosin II isoforms thus appear to have distinct enzymatic properties that may be of importance in carrying out their cellular functions.     

Biochemical and molecular characterization and expression of the 11S-type storage protein from Coffea arabica endosperm

In order to define better the endosperm protein content of commercial coffee species Coffea arabica (Arabica) and C. canephora (Robusta), the principal storage protein of coffee grains has been analysed by 2-dimensional electrophoresis (2DE) and amino acid microsequencing. The most abundant polypeptide spots observed on mature coffee grain 2DE profiles were found to be subunits of the same protein, which exists as multiple isoforms with varying pIs. Strong sequence similaritywas found to the 11S family of plant storage proteins. The structure is typical of the 11S type, which occurs as a precursor of 55 kDa, and is observed under denaturing and reducing conditions on 2DE profiles in the form of cleavage products at approximately 20 kDa (β arms) and 32 kDa (α arms). Differences between Arabica and Robusta 2DE profiles indicate a secondary 11S protein family in some varieties of the latter. The existence of multiple pI forms may indicate that a multigene family encodes for these proteins. We estimate that the protein accounts for approximately 45 % of total grain protein. A cloned full-length cDNA of 1 706 bp coding for one of the isoforms is described and discussed in relation to other coffee storage protein sequences.     

Quantum chemical study of the thermodynamics,kinetics of formation and bonding of H2CN relevance to prebiotic chemistry

Using the Iterative Extended Huckel Theory (IEHT), energy-conformation studies have been carried out for H₂CN (I),trans-HCNH (IIA), andcis-HCNH (IIB), three possible isomers formed by addition of a hydrogen atom to hydrogen cyanide. Calculations show that the order of decreasing thermodynamic stability is I≫IIA>IIB. Additionally, from calculated energies along simulated reaction pathways, the formation of I from HCN+H appears to be kinetically favored over IIA. Calculated properties of the minimum energy conformers of I and IIA are described and the potential role of H₂CN (I) as a reactive intermediate in prebiotic organic synthesis and its possible relevance to interstellar organic chemistry are discussed.     

Subunit Structure Differences in RNA Polymerase II Purified from Ungerminated versus Germinated Wheat Embryos

DNA-dependent RNA polymerase II (RNAP II) was purified from wheat embryos germinated for 0, 12, 24, and 36 hours and examined with several polyacrylamide gel electrophoretic systems. A changing electrophoretic pattern of RNAP II was observed on nondenaturing polyacrylamide gels. Subunit structure analysis by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) indicated that from ungerminated embryos, RNAP IIA was almost exclusively obtained which has a subunit structure identical to that established for wheat germ RNAP II previously (Jendrisak, Burgess 1977 Biochemistry 16: 1959-1964). Twelve polypeptides with molecular weights × 10⁻³ of 220, 140, 42, 40, 27, 25, 21, 20, 17.8, 17.0, 16.3, and 16.0 were routinely found to be associated with the purified enzyme. From embryos germinated for 36 hours, RNAP IIB was almost exclusively obtained which has a largest subunit of 180,000 mol wt instead of 220,000. From embryos germinated for 24 hours, an approximately equimolar mixture of RNAP IIA and IIB was obtained. Peptide maps of the 220,000 and 180,000 mol wt polypeptides of RNAP IIA and IIB were virtually identical, indicative of a precursor-product relationship for the two polypeptides. In addition to these results, SDS-PAGE indicated that the stoichiometry of the 27,000 mol wt polypeptide increased at the expense of the 25,000 mol wt polypeptide during germination and concomitantly with the appearance of the 180,000 molecular weight polypeptide. No modifications (e.g. gain, loss, or altered mobilities on analytical gels) in any of the other RNAP II subunits were observed in enzyme purified from embryos after various times of germination as determined by a variety of electrophoretic analyses under denaturing conditions.     

Characterization of phytoplankton assemblages in a tropical coastal environment using Kohonen self‐organizing map

This study was aimed at understanding the main abiotic environmental factors controlling the distribution patterns of abundance and composition of phytoplankton (size less than 10 μm) assemblages in the coastal waters of south‐eastern Côte d'Ivoire. Data were collected during two cruises, in January (low‐water period) and October (high‐water period) of 2014. A total of 67 species were identified and assigned to Bacillariophyceae (49%), Cyanophyceae (21%), Chlorophyceae (13%), Euglenophyceae (10%), Dinophyceae (4%) and Chrysophyceae (3%). Three biotic zones (I, IIA and IIB) were distinguishable on a Kohonen self‐organizing map after an unsupervised learning process. The diatom genera Eunotia sp., Navicula sp. and Actinoptychus senarius are significantly associated with I, IIA and IIB biotic zones, respectively. A clear seasonal cum salinity trend was apparent in phytoplankton distribution patterns. Turbidity and nitrate levels were the main abiotic factors controlling phytoplankton distribution in I, the upland tidal regions of the lagoon. In regions along the lagoon–sea continuum, phosphate and turbidity exert the most control during the low‐water season (IIA), while total dissolved solids control phytoplankton distribution during the high‐water season (IIB). These are climate‐sensitive parameters whose concentrations depend on prevailing hydroclimatic processes. Therefore, seasonality can have important consequences on phytoplankton community and inadvertently the productivity of these systems.     

Characterization of two sucrose synthase isoforms in sugarbeet root

Two sucrose synthase isoforms (EC 2.4.1.13) have been identified in developing sugarbeet (Beta vulgaris L.) roots. To aid in understanding the physiological significance of these multiple sucrose synthase isoforms, the two isoforms were partially purified and some of their physical and kinetic properties determined. Both isoforms were tetrameric proteins with native molecular masses of 320 kDa. The isoforms exhibited similar kinetic properties as well as similar changes in activity in response to changes in temperature. The isoforms differed, however, in their subunit composition. Sucrose synthase isoform I (SuSyI) was composed of two 84 kDa subunits and two 86 kDa subunits. Sucrose synthase isoform II (SuSyII) was a homotetramer with a subunit size of 86 kDa. The amino acid composition of the two subunits was similar, although differences in alanine, glycine, isoleucine and lysine content were noted. The activity of the two isoforms differed in response to varying pH conditions. The optimum pH for sucrose cleaving activity was observed at pH 6.0 and 6.5 for SuSyI and SuSyII, respectively. The optimum pH for sucrose synthesizing activity occurred at pH 7.5 and 7.0 for SuSyI and SuSyII, respectively. The observed differences in subunit composition and reactivity at different pH values suggest that multiple isoforms of sucrose synthase may provide a mechanism to regulate sucrose metabolism in sugarbeet root by differential regulation of expression of the two isoforms and modulation of their activity by changes in cellular pH.     

Purification and characterization of a secreted purple phosphatase from soybean suspension cultures

We purified and partially sequenced a purple (λ_max = 556 nanometers) acid phosphatase (APase; EC 3.1.3.2) secreted by soybean (Glycine max) suspension-culture cells. The enzyme is a metalloprotein with a Mn²⁺ cofactor. This APase appears to be a glycoprotein with a monomer subunit molecular weight of 58,000 and an active dimer molecular weight of approximately 130,000. The protein has an isoelectric point of about 5.0 and a broad pH optimum centered near 5.5. The purified enzyme, assayed with p-nitrophenyl phosphate as the substrate, has a specific activity of 512 units per milligram protein and a K_m of approximately 0.3 millimolar; phosphate is a competitive inhibitor with a K_i of 0.7 millimolar. This APase is similar to one found in soybean seed meal but dissimilar to that found in soybean seedlings.     

Simple procedures for determination of [14C] hydroxyproline.

Two improved and simplified procedures are presented for determination of [¹⁴C]hydroxyproline. Simplification is achieved by boiling samples without previous toluene extractions and, after boiling, passing the toluene extracts through a silicic acid column.Procedure I avoids incomplete toluene extraction of [¹⁴C]proline derivatives and uses instead a specific adsorption to a silicic acid column.Procedure IIA introduces inter alia the silicic acid column to reduce the interference of incompletely extracted [¹⁴C]proline.Procedure IIB simplifies procedure IIA by replacing extraction of [¹⁴C]proline derivatives with a silicic acid column.The new procedures are simple, handy, specific and reproducible methods for determination of [¹⁴C]hydroxyproline and are preferable to any other method known today. Procedure IIB is specially recommended for routine use.     

Electrophoretic microheterogeneity and subunit composition of the 13S coupling factors of oxidative and photosynthetic phosphorylation.

Two electrophoretically distinguishable species of the 13S coupling factor of oxidative phosphorylation from Alcaligenes faecalis are detectable by standard polyacrylamide gel electrophoresis in the absence of urea, detergents, or any other protein-denaturing reagents. The slower species (type IA) can be converted into the faster species (type IB) by treatment with ATP, and the fast form converts into the slow form when aged at 4 degrees. The enzyme undergoes these conversions both when it is free in solution and when it is membrane bound. The ATP analog adenylyl imidodiphosphate (AMP-PNP) gives the conversion without being hydrolyzed and without causing any apparent change in the mass of the protein, which suggests that the conversion may be a ligand-induced conformational change. Types IA and IB can convert into three other electrophoretically distinguishable species (types IIA, IIB, and III) if the purification procedure involves chromatography on a DEAE-Sephadex column equilibrated in phosphate buffer. These conversions can be prevented if the column is eluted in morpholinoethanesulfonic acid (Mes) buffer and KCl. Type IIA is convertible into type IIB by ATP treatment. Types IA and IB will also convert into types IIA and IIB and finally into type III when aged for extended periods of time at 4 degrees, without a detectable change in mass. Coupling factor activity is lost when type I enzyme converts into type II enzyme, as is the ability of the enzyme to bind to the membrane. However, ATPase activity does not change significantly. The mitochondrial 13S coupling factor shows up to three electrophoretically distinguishable species. The use of phosphate buffer during DEAE-Sephadex chromatography gives conversion of slower species into faster species. ATP treatment does not give interconversions, and aging at 4 degrees gives only a slow dissociation of the enzyme into subunits. The chloroplast 13S coupling factor also shows up to three electrophoretic species. Incubation with ATP does not give interconversions, but a temperature-dependent conversion of the major species into a faster species occurs upon aging. The subunit composition of the three 13S enzymes is very similar by polyacrylamide gel electrophoresis in sodium dodecyl sulfate, the major difference being in the number of classes of small polypeptides.     

Purification and characterization of three soluble invertases from barley (Hordeum vulgare L.) leaves.

Three soluble isoforms of invertase (beta-fructofuranosidase; EC 3.2.1.26) were purified from 7-d-old primary leaves of barley (Hordeum vulgare L.). Invertase I, a monomeric protein of 64 kD, was purified to apparent homogeneity as shown by sodium dodecylsulfate-polyacrylamide gel electrophoresis. Invertases IIA and IIB, multimeric proteins with molecular masses of the 116 and 155 kD, were purified 780- and 1370-fold, respectively, but were not yet homogeneous. Extracts of epidermal strips of leaves contained only invertase IIB. The specific activity of invertase was more than 100-fold higher in the epidermis than in the mesophyll. All three isoforms were acidic invertases, with pH optima of around 5.0 and little activity in the alkaline range. Invertase I had a Km for sucrose of 8.1 mM, and invertases IIA and IIB had much lower values of 1.0 and 1.7 mM, respectively. Invertase I was more than 2-fold more resistant than the other two invertases to the inhibitors HgCl2 and pyridoxal. All three constitutive invertases were found to act also as sucrose-sucrose fructosyltransferases when supplied with high concentrations of sucrose, forming 1-kestose as principal product. However, the fructosyltransferase activity of all three enzymes was inhibited by pyridoxal in the same way as their invertase activity. This characteristic clearly differentiates them from the inducible sucrose-sucrose fructosyltransferase of barley leaves, the activity responsible for the initial steps of fructan biosynthesis, which has previously been shown to be insensitive to pyridoxal.