Members of a New Group of Chitinase-Like Genes are Expressed Preferentially in Cotton Cells with Secondary Walls

Two homologous cotton (Gossypium hirsutum L.) genes, GhCTL1 and GhCTL2, encode members of a new group of chitinase-like proteins (called the GhCTL group) that includes other proteins from two cotton species, Arabidopsis, rice, and pea. Members of the GhCTL group are assigned to family GH19 glycoside hydrolases along with numerous authentic chitinases (http://afmb.cnrs-mrs.fr/CAZY/index.html), but the proteins have novel consensus sequences in two regions that are essential for chitinase activity and that were previously thought to be conserved. Maximum parsimony phylogenetic analyses, as well as Neighbor-Joining distance analyses, of numerous chitinases confirmed that the GhCTL group is distinct. A molecular model of GhCTL2 (based on the three-dimensional structure of a barley chitinase) had changes in the catalytic site that are likely to abolish catalytic activity while retaining potential to bind chitin oligosaccharides. RNA blot analysis showed that members of the GhCTL group had preferential expression during secondary wall deposition in cotton lint fiber. Cotton transformed with a fusion of the GhCTL2 promoter to the beta -d-glucuronidase gene showed preferential reporter gene activity in numerous cells during secondary wall deposition. Together with evidence from other researchers that mutants in an Arabidopsis gene within the GhCTL group are cellulose-deficient with phenotypes indicative of altered primary cell walls, these data suggest that members of the GhCTL group of chitinase-like proteins are essential for cellulose synthesis in primary and secondary cell walls. However, the mechanism by which they act is more likely to involve binding of chitin oligosaccharides than catalysis.     

Spectroscopic characterization and structural modeling of prolamin from maize and pearl millet

Biophysical methods and structural modeling techniques have been used to characterize the prolamins from maize (Zea mays) and pearl millet (Pennisetum americanum). The alcohol-soluble prolamin from maize, called zein, was extracted using a simple protocol and purified by gel filtration in a 70% ethanol solution. Two protein fractions were purified from seed extracts of pearl millet with molecular weights of 25.5 and 7 kDa, as estimated by SDS-PAGE. The high molecular weight protein corresponds to pennisetin, which has a high -helical content both in solution and the solid state, as demonstrated by circular dichroism and Fourier transform infrared spectra. Fluorescence spectroscopy of both fractions indicated changes in the tryptophan microenvironments with increasing water content of the buffer. Low-resolution envelopes of both fractions were retrieved by ab initio procedures from small-angle X-ray scattering data, which yielded maximum molecular dimensions of about 14 nm and 1 nm for pennisetin and the low molecular weight protein, respectively, and similar values were observed by dynamic light scattering experiments. Furthermore, ¹H nuclear magnetic resonance spectra of zein and pennisetin do not show any signal below 0.9 ppm, which is compatible with more extended solution structures. The molecular models for zein and pennisetin in solution suggest that both proteins have an elongated molecular structure which is approximately a prolate ellipsoid composed of ribbons of folded -helical segments with a length of about 14 nm, resulting in a structure that permits efficient packing within the seed endosperm.     

In vitro assay and light regulation of nitrate reductase in red alga Gracilaria chilensis

Nitrate reductase (NR) is the first enzyme in the nitrogen assimilation pathway. The in vitro NR activity of Gracilaria chilensis was assayed under different conditions to reveal its stability and biochemical characteristics, and an optimized in vitro assay is described. Maximal NR activities were observed at pH 8.0 and 15 degrees C. The apparent Km value for NADH was 8 microM and for nitrate 680 microM. Crude extracts of G. chilensis stored at 4 degrees C showed a 50% decrease of NR activity after 24 h. The highest NR activity value (253.20+/-2.60 x 10(-3) U g(-1)) was obtained when 100% von Stosch medium (500 microM NO3-) was added before extraction of apical parts. Algae under light:dark cycles of 12:12h exhibited circadian fluctuation of NR activity and photosynthesis with more than 2 times higher levels in the light phase. No evidence of endogenous diel rhythm controlling NR activity or photosynthesis was observed. Light pulses lasting 10 or 60 min during the darkness increased the NR activity by 30% and 45%, respectively. The results indicate that NR and photosynthesis are regulated mainly by light and not by a biological clock.     

High level production of supra molecular weight poly (3-hydroxybutyrate) by metabolically engineered<Emphasis Type="Italic">Escherichia coli</Emphasis>

The supra molecular weight poly ([R]-3-hydroxybutyrate) (PHB), having a molecular weight greater than 2 million Da, has recently been found to possess improved mechanical properties compared with the normal molecular weight PHB, which has a molecular weight of less than 1 million Da. However, applications for this PHB have been hampered due to the difficulty of its production. Reported here, is the development of a new metabolically engineeredEscherichia coli strain and its fermentation for high level production of supra molecular weight PHB. RecombinantE. coli strains, harboring plasmids of different copy numbers containing theAlcaligenes latus PHB biosynthesis genes, were cultured and the molecular weights of the accumulated PHB were compared. When the recombinantE. coli XL 1-Blue, harboring a medium-copy-number pJC2 containing theA. latus PHB biosynthesis genes, was cultivated by fed-batch culture at pH 6.0, supra molecular weight PHB could be produced at up to 89.8 g/L with a productivity of 2.07 g PHB/L-h. The molecular weight of PHB obtained under these conditions was as high as 22 MDa, exceeding by an order of magnitude the molecular weight of PHB typically produced inRalstonia eutropha or recombinantE. coli     

GRP94 reduces cell death in SH-SY5Y cells perturbated calcium homeostasis

The endoplasmic reticulum (ER) resident-94 kDa glucose-regulated protein (GRP94), plays a pivotal role in cell death due to ER stress. In our study expression of GRP94 was increased in human neuroblastoma SH-SY5Y cells due to exposure to calcium ionophore A23187. A23187-mediated cell death was associated with activation of the major cysteine proteases, caspase-3 and calpain. Pretreatment with adenovirus-mediated antisense GRP94 (AdGRP94AS) reduced viability of SH-SY5Y cells subjected to A23187 treatment compared with wild type cells or cells with adenovirus-mediated overexpression of GRP94 (AdGRP94S). These results indicated that suppression of GRP94 is associated with accelerated cell death. Moreover, expression of GRP94 suppressed A23187-induced cell death and stabilized calcium homeostasis.     

Aryl Acylamidase Activity on Acetylcholinesterase Is High During Early Chicken Brain Development

Acetylcholinesterase (AChE) and butyrylcholinesterase (BChE) are known to exhibit aryl acylamidase activities (here called AAA(AChe) and AAA(BChe), respectively), which have been suggested to be involved in developmental and pathological processes. We here have investigated the developmental profiles of both AAA(AChe) and AAA(BChe) activities along with their AChE and BChE activities from embryonic days E3 to hatching (E21) in Triton-extracted homogenates from chicken embryonic brains. AAA(AChe) follows continuously an increase that is typical for AChE expression itself, whereas AAA(BChe) was relatively high before E10 to then become negligible toward hatching. Sucrose gradient centrifugation of both homogenized and immunopurified samples from E6-E18 brains showed that all globular forms (G1, G2, G4) of AChE present AAA(AChe) activity. Interestingly, the ratio of AAA(AChe) to AChE is highest at E6, and here again higher on G1/G2- over the G4-form. Noticeably, the sensitivity of AAA(AChe) toward the specific AChE inhibitor BW284c51 at all stages is higher than that of AChE itself. These data of high ratios of AAA associated at young stages with cholinesterases strongly indicate a role of AAA in early brain development.     

SDS Induced Structural Changes in α-Crystallin and It’s Effect on Refolding

-Crystallin, a major eye lens protein and a key member of the small heat shock protein family, acts like a chaperone by preventing aggregation of substrate proteins. One of the hallmarks of most small heat shock proteins is their existence as a large oligomer, the role of which in its function is not understood at present. We have studied the role of the oligomer in the stability of its structure against SDS induced destabilization by CD measurements. -Crystallin from bovine source as well as recombinant preparation was used for this purpose. As SDS concentration was gradually increased, the -sheet structure was diminished followed by concomitant increase in the -helical structure. The quaternary structural changes in presence of SDS were also monitored by light scattering, polarization and anisotropy measurements. It was found that the breakdown of the oligomeric structure was nearly complete above 1 mM SDS concentration. The results were compared with that of a monomeric -crystallin, which is also a major -sheet protein like -crystallin. When -crystallin was first converted into monomeric random coil structure in presence of 6 M urea and allowed to refold in SDS solution, amount of -helix was more than that incubated directly in the same concentration of SDS. The results show that -crystallin attains extra structural stability against external stress due to its oligomeric structure. The implication for the extra stability is discussed in reference to its function as molecular chaperone.     

Utility of Amplified Fragment Length Polymorphisms (AFLP) to analyse genetic structures within the Alexandrium tamarense species complex

Phylogenetic analyses of the Alexandrium tamarense species complex using ribosomal RNA sequences show a differentiation of ribotypes/clades into geographic areas and not into the three morphotypes/species A. tamarense, A. fundyense and A. catenella. Different parts of the rRNA operon have proven informative in revealing the existence and the relationships of these geographic clades, whereas even internal transcribed spacer (ITS) regions lack the resolution required to gain a deeper insight into the population structure of the species complex. Here, the utility of the DNA fingerprinting technique Amplified Fragment Length Polymorphism (AFLP) as a possible tool for such purposes was tested. A mixed sampling strategy was used in order to assess the amount of variation of AFLP banding patterns at the level of populations and geographic clades. We also describe optimized methods to achieve a good reproducibility. Our results suggest that AFLPs can provide useful information at the population level using clonal samples from a certain bloom, whereas the amount of variation that we found is too high to allow for meaningful comparisons of a few strains collected from different localities at different time points even though they belong to one geographic clade.     

The brain's calendar: neural mechanisms of seasonal timing

The suprachiasmatic nucleus (SCN) of the hypothalamus is the principal component of the mammalian biological clock, the neural timing system that generates and coordinates a broad spectrum of physiological, endocrine and behavioural circadian rhythms. The pacemaker of the SCN oscillates with a near 24 h period and is entrained to the diurnal light-dark cycle. Consistent with its role in circadian timing, investigations in rodents and non-human primates furthermore suggest that the SCN is the locus of the brain's endogenous calendar, enabling organisms to anticipate seasonal environmental changes. The present review focuses on the neuronal organization and dynamic properties of the biological clock and the means by which it is synchronized with the environmental lighting conditions. It is shown that the functional activity of the biological clock is entrained to the seasonal photic cycle and that photoperiod (day length) may act as an effective zeitgeber. Furthermore, new insights are presented, based on electrophysiological and molecular studies, that the mammalian circadian timing system consists of coupled oscillators and that the clock genes of these oscillators may also function as calendar genes. In summary, there are now strong indications that the neuronal changes and adaptations in mammals that occur in response to a seasonally changing environment are driven by an endogenous circadian clock located in the SCN, and that this neural calendar is reset by the seasonal fluctuations in photoperiod.