A facile comparative approach towards utilization of waste cotton lint for the synthesis of nano-crystalline cellulose crystals along with acid recovery.

There is a need for reuse of waste cotton lint (WCL) from the blow room of yarn spinning mills. The drive to use this material for the synthesis of nanocellulose is difficult because of the several purification/pretreatment processes. Here, we developed a combined single bath purification process of WCL and utilized it for the synthesis of nano-crystalline cellulose crystals (NCs) which are valuable nanomaterials with novel properties along with acid recovery for reuse. The micrograph of the synthesized NCs confirmed a network of nano-sized crystalline cellulose crystals having nano ranged diameter of NCs isolated by two processes. The FTIR result established the removal of impurities and hemicelluloses from WCL. The crystallinity index of WCL (∼89.97%) is improved to ∼96% and ∼94% for sulphuric acid and nitric acid synthesized NCs (NC1 and NC2). The crystallite size of WCL, CTWCL, NC1, and NC2 was calculated using XRD and found to be 101.56, 103.54, 98.81, and 95.6nm respectively. The hydrodynamic size (Z-average) (dnm), polydispersity index and zeta potential of NCs was also studied using dynamic light scattering (DLS). The thermal stability of the NC1 is better than that of NC2. These NCs can be used as reinforcing filler/barrier material.

Synthesis and biophysical evaluation of 2',4'-constrained 2'O-methoxyethyl and 2',4'-constrained 2'O-ethyl nucleic acid analogues.

We have recently shown that combining the structural elements of 2'O-methoxyethyl (MOE) and locked nucleic acid (LNA) nucleosides yielded a series of nucleoside modifications (cMOE, 2',4'-constrained MOE; cEt, 2',4'-constrained ethyl) that display improved potency over MOE and an improved therapeutic index relative to that of LNA antisense oligonucleotides. In this report we present details regarding the synthesis of the cMOE and cEt nucleoside phosphoramidites and the biophysical evaluation of oligonucleotides containing these nucleoside modifications. The synthesis of the cMOE and cEt nucleoside phosphoramidites was efficiently accomplished starting from inexpensive commercially available diacetone allofuranose. The synthesis features the use of a seldom used 2-naphthylmethyl protecting group that provides crystalline intermediates during the synthesis and can be cleanly deprotected under mild conditions. The synthesis was greatly facilitated by the crystallinity of a key mono-TBDPS-protected diol intermediate. In the case of the cEt nucleosides, the introduction of the methyl group in either configuration was accomplished in a stereoselective manner. Ring closure of the 2'-hydroxyl group onto a secondary mesylate leaving group with clean inversion of stereochemistry was achieved under surprisingly mild conditions. For the S-cEt modification, the synthesis of all four (thymine, 5-methylcytosine, adenine, and guanine) nucleobase-modified phosphoramidites was accomplished on a multigram scale. Biophysical evaluation of the cMOE- and cEt-containing oligonucleotides revealed that they possess hybridization and mismatch discrimination attributes similar to those of LNA but greatly improved resistance to exonuclease digestion.

Deamidation of specific glutamine residues from alpha-A crystallin during aging of the human lens.

Although it has been hypothesized that age-dependent deamidation of glutamine and/or asparagine residues may play an important role in the turnover of proteins in vivo, surprisingly little is known concerning the extents of deamidation of biologically important proteins with very long half-lives. Alpha-A crystallin is the most abundant protein of the adult human lens, which contains long-lived proteins in the central fetal-embryonic region that were synthesized before birth of the individual. Peptides, corresponding to tryptic fragments of alpha-A crystallin, were synthesized with either the expected glutamine-6, glutamine-50, and glutamine-147 residues, or deamidated glutamic acid residues at the same positions. These synthetic peptides were used to identify and quantitate the amidated versus deamidated forms of each tryptic fragment of alpha-A crystallin from the fetal-embryonic region of lenses from donors of increasing age up to 64 years old. The results demonstrate that all three glutamine residues are very stable, with glutamine-50 undergoing a maximum of approximately 30% deamidation after 64 years postsynthesis, while glutamine-6 and glutamine-147 undergo no detectable deamidation during the same period of time. Together, these results are consistent with the hypothesis that resistance to age-dependent, nonenzymatic deamidation may be an important prerequisite for the stability of proteins in vivo.

The carboxy-terminal lysine of alpha B-crystallin is an amine-donor substrate for tissue transglutaminase.

A hexapeptide, corresponding to the sequence around the glutamine in beta A3-crystallin that functions as amine-acceptor for transglutaminase, was synthesized. This peptide was biotinylated and used as a probe to identify amine-donor substrates for transglutaminase among lens proteins. It was found that Ca(2+)-activated transglutaminase linked this peptide not only to several beta-crystallins but, unexpectedly, also to alpha B-crystallin. The C-terminal lysine residue of alpha B-crystalline could be identified as the site of linkage. This strengthens the notion that, at least in crystallins, all transglutaminase substrate residues are located in terminal extensions of the polypeptides. It was shown that in lens homogenate, alpha B-crystallin can be covalently crosslinked to beta-crystallins by transglutaminase. The transglutaminase-mediated crosslinking of alpha B-crystallin may have implications for its involvement in normal and pathological processes in lens and other tissues.

Antisera to alpha crystallin as probes to study changes in lens proteins during human cataractogenesis.

Antisera have been made to synthetic peptides that correspond to eight different regions of the alpha A molecule. Together with a solid phase radioimmunoassay, these antisera have been used to quantitatively assess binding to enriched alpha crystallin preparations from six different cataractous and six different normal lenses. Seven of the eight antisera show no difference in binding to alpha crystallin from cataractous versus normal lenses, whereas the antiserum directed against the alpha A sequence 120-130 shows a statistically significant decrease in binding to the alpha crystallin from cataractous lenses. Together, these studies demonstrate the feasibility of using antipeptide sera as probes of polypeptide changes during cataractogenesis and suggest that the region of the alpha A crystallin molecule encompassing residues 120-300 may undergo covalent and/or noncovalent structural modification during the process of opacification in the human senile lens.