Description of a new species of the genus Awaous Valenciennes, 1837 (Gobiiformes: Oxudercidae) from the middle stretch of the Mahanadi River,Odisha, India,with comments on the Awaous species from India

A new species of the genus Awaous (Oxudercidae), Awaous motla sp. nov., is described based on 18 specimens collected from the Mahanadi River near Sonepur, Subarnapur District, and 3 specimens from the same river near Boudh bridge, Boudh District of Odisha, India. This species is distinct from its congeners by having a combination of characteristics: relatively small eyes, diameter of 6.6–8.4 in head length (LH); robust and long snout, 2.0–2.6 in LH; eye diameter 2.7–4.1 in snout length; cephalic sensory pore system interrupted with eight pores; predorsal scales 13–15; longitudinal scale series 55–58; gill rakers 2 + 1 + (6–7) on the first gill arch; teeth small, conical, and in a single row on the upper jaw and multiserial (2–3) on the lower jaw. This species is also differentiated from some of its congeners in the nucleotide composition of the cytochrome c oxidase I gene by 8.3%–13.8% Kimura two-parameter (K2P) distance and belongs to a separate cluster in the maximum likelihood tree analysis. This finding is also supported by the species delimitation analysis based on Assemble Species by Automatic Partitioning. The new species holds high commercial value in its locality and needs special conservation attention for sustainable utilization.     

Improvement of small seed for big nutritional feed

Exploding global population, rapid urbanization, salinization of soils, decreasing arable land availability, groundwater resources, and dynamic climatic conditions pose impending damage to our food security by reducing the grain quality and quantity. This issue is further compounded in arid and semi-arid regions due to the shortage of irrigation water and erratic rainfalls. Millets are gluten (a family of proteins)-free and cultivated all over the globe for human consumption, fuel, feed, and fodder. They provide nutritional security for the under- and malnourished. With the deployment of strategies like foliar spray, traditional/marker-assisted breeding, identification of candidate genes for the translocation of important minerals, and genome-editing technologies, it is now tenable to biofortify important millets. Since the bioavailability of iron and zinc has been proven in human trials, the challenge is to make such grains accessible. This review encompasses nutritional benefits, progress made, challenges being encountered, and prospects of enriching millet crops with essential minerals.     

Characterization of a mildly alkalophilic and thermostable recombinant <Emphasis Type="Italic">Thermus thermophilus</Emphasis> laccase with applications in decolourization of dyes

Objective

To examine the potential for applications of TthLAC, a monomeric (~ 53 kDa) laccase encoded by the genome of Thermus thermophilus (strain HB 27) which can be produced at low cost in Escherichia coli.

Result

Functional, thermostable and mildly alkalophilic TthLAC of high purity (> 90%) was produced through simple heating of suspended (TthLAC overexpressing) E.coli cells at 65 °C. For reactions of short duration (< 1 h) the temperature for optimal activity is ~ 90 °C. However, TthLAC undergoes slow partial unfolding and thermal inactivation above 65 °C, making it unsuitable for long incubations above this temperature. With different substrates, optimal function was observed from pH 6 to 8. With the substrate, ABTS, catalytic efficiency (K _m) and maximum velocity (V_max) at 60 °C and pH 6.0 were determined to be 2.4 × 10³ µM and 0.04 × 10³ µM/min respectively. Ultra-pure, affinity-purified TthLAC was used to confirm and characterize the enzyme’s ability to oxidize known (laccase) substrates such as ABTS, syringaldazine and 4-fluoro-2-methylphenol. TthLAC decoloured up to six different industrial dyes, with or without the use of redox mediators such as ABTS.

Conclusions

Unlike versatile laccases from most other sources, which tend to be thermolabile as well as acidophilic, TthLAC is a versatile, thermostable, mildly alkalophilic laccase which can be produced at low cost in E.coli for various redox applications.

     

Overexpression of [delta]-Pyrroline-5-Carboxylate Synthetase Increases Proline Production and Confers Osmotolerance in Transgenic Plants

Proline (Pro) accumulation has been correlated with tolerance to drought and salinity stresses in plants. Therefore, overproduction of Pro in plants may lead to increased tolerance against these abiotic stresses. To test this possibility, we overexpressed in tobacco the mothbean [delta]-pyrroline-5-carboxylate synthetase, a bifunctional enzyme able to catalyze the conversion of glutamate to [delta]-pyrroline-5-carboxylate, which is then reduced to Pro. The transgenic plants produced a high level of the enzyme and synthesized 10- to 18-fold more Pro than control plants. These results suggest that activity of the first enzyme of the pathway is the rate-limiting factor in Pro synthesis. Exogenous supply of nitrogen further enhanced Pro production. The osmotic potentials of leaf sap from transgenic plants were less decreased under water-stress conditions compared to those of control plants. Overproduction of Pro also enhanced root biomass and flower development in transgenic plants under drought-stress conditions. These data demonstrated that Pro acts as an osmoprotectant and that overproduction of Pro results in the increased tolerance to osmotic stress in plants.     

Toxicity and tolerance of aluminum in plants: tailoring plants to suit to acid soils

Aluminum (Al) stress is one of the serious limiting factors in plant productivity in acidic soils, which constitute about 50 % of the world’s potentially arable lands and causes anywhere between 25 and 80 % of yield losses depending upon the species. The mechanism of Al toxicity and tolerance has been examined in plants, which is vital for crop improvement and enhanced food production in the future. Two mechanisms that facilitate Al tolerance in plants are Al exclusion from the roots and the ability to tolerate Al in the symplast or both. Although efforts have been made to unravel Al-resistant factors, many aspects remain unclear. Certain gene families such as MATE, ALMT, ASR, and ABC transporters have been implicated in some plants for resistance to Al which would enhance the opportunities for creating crop plants suitable to grow in acidic soils. Though QTLs have been identified related to Al-tolerance, no crop plant that is tolerant to Al has been evolved so far using breeding or molecular approaches. The remarkable changes that plants experience at the physiological, biochemical and molecular level under Al stress, the vast array of genes involved in Al toxicity-tolerance, the underlying signaling events and the holistic image of the molecular regulation, and the possibility of creating transgenics for Al tolerance are discussed in this review.     

Identification,characterization, validation and cross-species amplification of genic-SSRs in Indian Mustard (<Emphasis Type="Italic">Brassica juncea</Emphasis>)

Brassica juncea is an economically important oilseed crop worldwide. It has limited genomic resources at present. We generated 47,962,057 expressed sequence reads which were assembled into 45,280 unigenes. A total of 4108 SSR loci (≥10 bp) were identified in these unigenes. Trinucleotide was the most frequent repeat unit (59.91 %) followed by di- (38.66 %), tetra - (0.71 %), hexa - (0.49 %) and pentanucleotide repeats (0.24 %). Primers were designed for 2863 SSR loci among which 460 were selected for primer synthesis. A total of 339 loci amplified successfully of which 134 (39.5 %) exhibited polymorphism among six B. juncea genotypes with PIC values ranging from 0.18 to 0.81. Further, 25 polymorphic SSRs were used for analysis of genetic variability in 25 genotypes of Brassicas and their wild relatives. Two to five alleles with PIC values 0.22–0.66 were detected at these loci. The dendrogram grouped the genotypes according to their known pedigree/systematic position.     

Activities of Phenylalanine- and Tyrosine-Ammonia Lyases and Aminotransferases during Organogenesis in Callus Cultures of Rice

Activities of key enzymes involved in the shikimic acid pathway,namely, phenylalanine ammonia-lyase, tyrosine ammonia-lyase,phenylalanine aminotransferase and tyrosine aminotransferase,were examined during initiation of roots and shoots in calluscultures of rice. Enhancement of the activities of tyrosine-ammonialyase and tyrosine aminotransferase but not of phenylalanine-ammonialyase and phenylalanine aminotransferase was observed in organ-formingcultures, as compared to activities of these enzymes in non-organ-formingcultures. The role of these enzymes in such organogenetic processesis discussed (Received March 16, 1988; Accepted October 19, 1988)     

Regeneration of plants from long-term cultures of Oryza sativa L.

Root and embryo derived callus tissues of rice grown on sucrose alone as carbon source lost their ability to organise shoots by 75 and 100 days in culture respectively. Along with 2% sucrose, either 3% sorbitol or 3% mannitol was found to be necessary in the growth medium for the callus to regenerate whole plants over a period of 1400 days without any decline in the shoot forming ability. Our results indicated that incorporation of sorbitol or mannitol in the callus proliferating medium provides long-term totipotent rice cultures with a high frequency (50–60%) of shoot differentiation.