Stabilization of collagen through bioconversion: An insight in protein–protein interaction

Collagen is a natural protein, which is used as a vital biomaterial in tissue engineering. The major concern about native collagen is lack of its thermal stability and weak resistance to proteolytic degradation. In this scenario, the crosslinking compounds used for stabilization of collagen are mostly of chemical nature and exhibit toxicity. The enzyme mediated crosslinking of collagen provides a novel alternative, nontoxic method for stabilization. In this study, aldehyde forming enzyme (AFE) is used in the bioconversion of hydroxylmethyl groups of collagen to formyl groups that results in the formation of peptidyl aldehyde. The resulted peptidyl aldehyde interacts with bipolar ions of basic amino acid residues of collagen. Further interaction leads to the formation of conjugated double bonds (aldol condensation involving the aldehyde group of peptidyl aldehyde) within the collagen. The enzyme modified collagen matrices have shown an increase in the denaturation temperature, when compared with native collagen. Enzyme modified collagen membranes exhibit resistance toward collagenolytic activity. Moreover, they exhibited a nontoxic nature. The catalytic activity of AFE on collagen as a substrate establishes an efficient modification, which enhances the structural stability of collagen. This finds new avenues in the context of protein–protein stabilization and discovers paramount application in tissue engineering. © 2014 Wiley Periodicals, Inc. Biopolymers 101: 903–911, 2014.     

Use of 2-aminopurine fluorescence to study the role of the beta hairpin in the proofreading pathway catalyzed by the phage T4 and RB69 DNA polymerases

For DNA polymerases to proofread a misincorporated nucleotide, the terminal 3-4 nucleotides of the primer strand must be separated from the template strand before being bound in the exonuclease active center. Genetic and biochemical studies of the bacteriophage T4 DNA polymerase revealed that a prominent beta-hairpin structure in the exonuclease domain is needed to efficiently form the strand-separated exonuclease complexes. We present here further mutational analysis of the loop region of the T4 DNA polymerase beta-hairpin structure, which provides additional evidence that residues in the loop, namely, Y254 and G255, are important for DNA replication fidelity. The mechanism of strand separation was probed in in vitro reactions using the fluorescence of the base analogue 2-aminopurine (2AP) and mutant RB69 DNA polymerases that have modifications to the beta hairpin, to the exonuclease active site, or to both. We propose from these studies that the beta hairpin in the exonuclease domain of the T4 and RB69 DNA polymerases functions to facilitate strand separation, but residues in the exonuclease active center are required to capture the 3' end of the primer strand following strand separation.     

Photophysical behaviour of 1-(4-N,N-dimethylaminophenylethynyl)pyrene (DMAPEPy) in homogeneous media.

The photophysical behaviour of a new pyrene derivative, 1-(4-N,N-dimethylaminophenylethynyl)pyrene (DMAPEPy), in various solvents has been studied. Due to the presence of an ethynyl link with a cylindrical pi cloud between the donor (N,N-dimethyl group) and the acceptor (pyrene), the molecule shows efficient intramolecular charge transfer, with a high extinction coefficient in all the solvents. There is significant solvatochromism in the fluorescence with a large increase in the Stokes' shift of around 125 nm between n-hexane and acetonitrile. The solvent-dependent spectral data show a good correlation with the Kamlet-Taft solvent polarity parameter (pi*). The plots of Stokes' shifts with E(T)(30) are linear for non-protic solvents and for protic solvents but with different slopes. The fluorescence quantum yields are high for non-polar solvents and decrease as the solvent polarity increases. Unlike the parent molecule pyrene, DMAPEPy shows a short lifetime, which is fairly insensitive to oxygen-induced quenching and is dependent on solvent polarity. The molecule shows high steady-state fluorescence anisotropy, which is very sensitive to the viscosity change of the medium.     

Isolation and Characterization of Salt Tolerant Plant Growth Promoting Rhizobacteria from Plants Grown in Tsunami Affected Regions of Andaman and Nicobar Islands

In order to explore salt tolerant plant growth promoting rhizobacteria (PGPR), 121 isolates were recovered from Tsunami affected area of Andaman and Nicobar Islands, India, out of which 23 were grown at 10% NaCl. Out of total isolates grown at 10% NaCl concentration, 14 solubilized phosphate, 13 showed siderophore production, five showed Indole acetic acid (IAA) production and 16 produced one or more extra cellular enzymes. Isolates SJ10 and CR5 showed the highest enzyme production and PGP properties and five isolates showed antagonistic activity against Sclerotium rolfsii. Screening of potential isolates for nitrogen fixing gene (nifH) showed only three isolates (MM3, MM6 and MRC11) possessed nifH gene. Salt tolerant Bacillus PGPR could be used as a bio-inoculant to enhance the crop growth under Tsunami affected soils.     

Localization of Cytochrome b-559 in the Chloroplast Thylakoid Membranes in Spinach

Cytochrome b-559 was purified from spinach leaves and antibodies were made against it in rabbit. Using affinity-purified, monospecific antibodies, we have found that cytochrome b-559, which is closely associated with the primary photochemical activity of photosystem II, is localized exclusively in the grana thylakoids.     

Genotyping antibiotic producing fluorescent pseudomonads to select effective rhizobacteria for the management of major vanilla diseases

The genotypic diversity that occurs in antagonistic microorganisms provides an enormous resource for improving biological control of plant diseases. In this study, the diversity of 2,4-diacetylphloroglucinol (DAPG) and phenazine-1-carboxylic acid (PCA) producingPseudomonas sp. from different vanilla plantations of three different regions were studied. Out of eighty-five isolates of rhizobacteria from native soils of vanilla plantations, forty-four were positive to PCR amplification of a 560 bp fragment, which is specific of the genusPseudomonas. Among the forty-four isolates, twenty-one exhibited more antimicrobial activity against fungal pathogensviz., Fusarium oxysporum f. sp.vanillae (Tucker) Gordon,Phytophthora meadii McRae andColletotrichum vanillae underin vitro conditions. Twenty-one and sevenPseudomonas showed positive amplification for DAPG and phenazine respectively. An analysis of the level of biodiversity with DAPG and PCA producers at the species level was performed by comparing the restriction patterns of the genus specific 16S–23S ribosomal DNAs (rDNAs) amplified by PCR. This allowed us to cluster the isolates into four different amplified rDNA restriction analysis (ARDRA) groups. Eventually, it was found that some of the DAPG and PCA producers, which originated from different locations, fall under the same cluster. Bacterisation of vanilla plants with antibiotic producing fluorescent pseudomonads isolates resulted in a significant reduction of major diseases in vanilla both in glasshouse and field conditions.     

Identification of Bilirubin Binding Site in Type I Collagen

The interaction of bilirubin with collagen in the significance of jaundice incidence have been previously reported and investigated. The novel peptide sequences containing bilirubin binding domain was identified and located to develop a basis for further studies investigating the interactions of collagen with bilirubin in the present study. In this study an intricate interaction between bilirubin and collagen was characterized and their binding domain has been established using in-gel digestion and LC–MS/MS analysis based on the collagen sequencing and peptide mass fingerprinting. The biotinylated bilirubin derivatives bind to α₁(I) chain but not to α₂(I) chains which clearly designates that bilirubin shows greater affinity to α₁ chains of collagen. The intact proteins collected after analyzing the resulting complex mixture of peptides was used for peptide mapping. Using the electrospray method, among the other peptide sequence information obtained, the molecular weight of collagen alpha-2(I) chain was obtained by locating a 130 kDa weight peptide sequences with greater pi value (9.14) with 1,364 amino acid residues and collagen alpha-1(I) chain with 1,463 amino acid residues with 138.9 kDa molecular weight. This information leads to locate the exact sequence of these helices focussing on the domain identification. The total charge of the peptide domain sequences infers that the bilirubin participates in the electrostatic mode of interaction with collagen peptide. Moreover, other modes of interactions such as hydrogen bonding, covalent interactions and hydrophobic interactions are possible.     

Photophysical properties of Newkome-type dendrimers in aqueous medium.

Newkome-type first, second and third generation dendrimers, having t-butyl (GB), ethyl (GE) and carboxylic (GA) end groups, were synthesized. A pyrene group, which can act as fluorescent sensor, was attached to the core of the dendrimers and their photophysical properties in aqueous solution were studied. These dendrimers were found to aggregate in aqueous solution, which manifested as an excimer peak in the pyrene emission spectra for the first and second generation dendrimers with ethyl and t-butyl end groups. The excimer peak however was not seen in case of the third generation dendrimer. Dendrimers with carboxylic end groups, did not show the excimer peak in water, which implies the hydrophobic nature of the aggregation. It is observed that the intensity of the excimer peak decreases with the increase in the size of the dendrimer. Lifetime studies carried out on the first and second generation dendrimers showed the formation of excimer species as a risetime in the decay curve. The aggregation of the third generation dendrimer was proposed from the quenching studies using silver ions and CCl(4) as quenchers.     

Insertion/deletion polymorphisms in tribal populations of southern India and their possible evolutionary implications

India has the unique distinction of having perhaps the largest diversities, both biological and cultural. The Nilgiri Hills of southern India, a home for several tribal pockets representing different genetic isolates, provides a genetic wealth to understand human evolution. We have analyzed eight widely distributed polymorphic insertion/deletion loci (AluAPO, AluACE, AluDI, AluPLAT, AluPV92, AluFXIIIB, CD4 del and mtNUC) in 250 unrelated individuals from five tribal populations (Badaga, Irula, Kota, Kurumba, and Toda). All loci were highly polymorphic except the CD4 del locus, at which the deletion allele was fixed in Kotas and Kurumbas. The levels of average heterozygosities were found to be high in all the populations. In most populations, they were also higher than those predicted by the island model of population structure. The gene diversity (GST = 8.3%) was found to be higher than that in populations of most global regions with the exception of Africa. It is clear from the present study that drift effects could have accentuated the process of genetic differentiation of the tribal populations. The possibility of an early demographic expansion of modern humans within south India also cannot be ruled out.     

The Defective Proteasome but Not Substrate Recognition Function Is Responsible for the Null Phenotypes of the Arabidopsis Proteasome Subunit RPN10

Ubiquitylated substrate recognition during ubiquitin/proteasome-mediated proteolysis (UPP) is mediated directly by the proteasome subunits RPN10 and RPN13 and indirectly by ubiquitin-like (UBL) and ubiquitin-associated (UBA) domain-containing factors. To dissect the complexity and functional roles of UPP substrate recognition in Arabidopsis thaliana, potential UPP substrate receptors were characterized. RPN10 and members of the UBL-UBA–containing RAD23 and DSK2 families displayed strong affinities for Lys-48–linked ubiquitin chains (the major UPP signals), indicating that they are involved in ubiquitylated substrate recognition. Additionally, RPN10 uses distinct interfaces as primary proteasomal docking sites for RAD23s and DSK2s. Analyses of T-DNA insertion knockout or RNA interference knockdown mutants of potential UPP ubiquitin receptors, including RPN10, RPN13, RAD23a-d, DSK2a-b, DDI1, and NUB1, demonstrated that only the RPN10 mutant gave clear phenotypes. The null rpn10-2 showed decreased double-capped proteasomes, increased 20S core complexes, and pleiotropic vegetative and reproductive growth phenotypes. Surprisingly, the observed rpn10-2 phenotypes were rescued by a RPN10 variant defective in substrate recognition, indicating that the defectiveness of RPN10 in proteasome but not substrate recognition function is responsible for the null phenotypes. Our results suggest that redundant recognition pathways likely are used in Arabidopsis to target ubiquitylated substrates for proteasomal degradation and that their specific roles in vivo require further examination.