Nuclear DNA content of Pongamia pinnata L. and genome size stability of in vitro-regenerated plantlets

Pongamia pinnata L. is a multipurpose versatile legume that is well known as a prospective feedstock biodiesel species. However, to date, there has been little genomic research aimed at the exploitation of the biotechnological potential of this species. Genetic characterization of any plant is a challenging task when there is no information about the genome size and organization of the species. Therefore, the genome size of P. pinnata was estimated by flow cytometry with respect to two standards (Zea mays and Pisum sativum), and compared with that of in vitro-raised plants (nodal segment, in vitro-rooted plantlets and acclimatized in vitro plants) to study the potential effect of somaclonal variation on genome size. This method can be used to support the establishment of true-to-type plants to encourage afforestation programs. Modified propidium iodide/hypotonic citrate buffer was used for isolation of the intact nuclei. The 2C DNA value of this species was estimated to be 2.51?±?0.01 pg. Statistically, there was no significant difference in the DNA content of the in vitro-grown plants and mother plant at α?=?0.05. As a result of the low genome size of P. pinnata, a species that has adapted itself to a wide range of edaphic and ecological condition, we can now proceed for its next generation sequencing and genomic diversity studies.     

Draft Genome Sequences of Yersinia pestis Strains from the 1994 Plague Epidemic of Surat and 2002 Shimla Outbreak in India

We report the first draft genome sequences of the strains of plague-causing bacteria, Yersinia pestis, from India. These include two strains from the Surat epidemic (1994), one strain from the Shimla outbreak (2002) and one strain from the plague surveillance activity in the Deccan plateau region (1998). Genome size for all four strains is ~4.49 million bp with 139–147 contigs. Average sequencing depth for all four genomes was 21x.     

Structural and kinetic bases for the metal preference of the M18 aminopeptidase from Pseudomonas aeruginosa

The peptidases in clan MH are known as cocatalytic zinc peptidases that have two zinc ions in the active site, but their metal preference has not been rigorously investigated. In this study, the molecular basis for metal preference is provided from the structural and biochemical analyses. Kinetic studies of Pseudomonas aeruginosa aspartyl aminopeptidase (PaAP) which belongs to peptidase family M18 in clan MH revealed that its peptidase activity is dependent on Co²⁺ rather than Zn²⁺: the k_cat (s⁻¹) values of PaAP were 0.006, 5.10 and 0.43 in no-metal, Co²⁺, and Zn²⁺ conditions, respectively. Consistently, addition of low concentrations of Co²⁺ to PaAP previously saturated with Zn²⁺ greatly enhanced the enzymatic activity, suggesting that Co²⁺ may be the physiologically relevant cocatalytic metal ion of PaAP. The crystal structures of PaAP complexes with Co²⁺ or Zn²⁺ commonly showed two metal ions in the active site coordinated with three conserved residues and a bicarbonate ion in a tetragonal geometry. However, Co²⁺- and Zn²⁺-bound structures showed no noticeable alterations relevant to differential effects of metal species, except the relative orientation of Glu-265, a general base in the active site. The characterization of mutant PaAP revealed that the first metal binding site is primarily responsible for metal preference. Similar to PaAP, Streptococcus pneumonia glutamyl aminopeptidase (SpGP), belonging to aminopeptidase family M42 in clan MH, also showed requirement for Co²⁺ for maximum activity. These results proposed that clan MH peptidases might be a cocatalytic cobalt peptidase rather than a zinc-dependent peptidase.     

Recent advances in biochemistry and biotechnological synthesis of avermectins and their derivatives

Avermectins (AVMs), produced by Streptomyces avermitilis MA-4680 (or ATCC 31267, NRRL 8165, NCBIM 12804), are 16-member macrocylic lactones that play very important functions as bactericidal and antiparasitic agents against nematodes and anthropods, as well as Mycobacterium tuberculosis H37Rv. Since its discovery in 1975, use of AVM has been widely spreading around the globe. To date, the whole genome sequence of S. avermitilis K139 has been acquired, in which the AVM biosynthetic gene cluster was the most highly investigated to mine the genes responsible for functional as well as regulatory roles. Therefore, significant progress has been achieved for understanding and manipulating the biosynthesis, improved production, regulation mechanism, side effects, as well as the resistance of AVMs and their derivatives. These findings will facilitate further strain improvement and biosynthesis of novel derivatives bearing stable and improved biological activities, as well as overcoming the resistance mechanism to open up a bright period for these compounds. In this review, we have summarized and analyzed the update in advanced progress in biochemistry and biotechnological approaches used for the production of AVMs and their derivatives.     

Groupwise sampling: a strategy to sample core entries from RAPD marker data with application to mulberry

Key message

A strategy for effective utilization of RAPD marker data for sampling diverse entries was suggested and utilized for the development of mulberry core collection.

Abstract

Mulberry (Morus spp.) is a perennial tree cultivated mainly for its foliage in sericulture industry and also known for its edible fruits, fodder, and valued timber. In recent years, mulberry cultivation is confronted with several abiotic and biotic stresses due to inimical climatic factors and this has necessitated the genetic improvement of the crop. Core collection is an efficient way of harnessing the trait variation and novel genes available in a natural gene pool for the development of improved elite lines. In this study, we analyzed 850 mulberry accessions assembled from 23 countries with separate sets of polymorphic RAPD markers along with a limited number of ISSR, SSR, and phenotypic markers. A total of 75 accessions were duplicated in 20 clusters among five natural groups. The limitations of the RAPD marker system like problem in cross gel comparison were tackled by adopting a novel “Groupwise sampling” approach. A mulberry core collection with 100 diverse entries was selected using maximization method implemented in MSTRAT software. The mean Dice dissimilarity coefficient computed from marker data was 0.308 among core entries. Indigenous and exotic entries were not discriminated in cluster and principal component analysis supporting the spread of mulberry far from the place of origin. Accessions belonging to two wild mulberry species from Andaman Islands and Himalayan region formed separate clusters indicating the geographical, reproductive, and taxonomic distinction. The identified core collection will be available for researchers for intensive mining of desirable alleles in mulberry improvement as well as in genome resequencing program.     

Regulation of intestinal mucosal growth by amino acids

Amino acids, especially glutamine (GLN) have been known for many years to stimulate the growth of small intestinal mucosa. Polyamines are also required for optimal mucosal growth, and the inhibition of ornithine decarboxylase (ODC), the first rate-limiting enzyme in polyamine synthesis, blocks growth. Certain amino acids, primarily asparagine (ASN) and GLN stimulate ODC activity in a solution of physiological salts. More importantly, their presence is also required before growth factors and hormones such as epidermal growth factor and insulin are able to increase ODC activity. ODC activity is inhibited by antizyme-1 (AZ) whose synthesis is stimulated by polyamines, thus, providing a negative feedback regulation of the enzyme. In the absence of amino acids mammalian target of rapamycin complex 1 (mTORC1) is inhibited, whereas, mTORC2 is stimulated leading to the inhibition of global protein synthesis but increasing the synthesis of AZ via a cap-independent mechanism. These data, therefore, explain why ASN or GLN is essential for the activation of ODC. Interestingly, in a number of papers, AZ has been shown to inhibit cell proliferation, stimulate apoptosis, or increase autophagy. Each of these activities results in decreased cellular growth. AZ binds to and accelerates the degradation of ODC and other proteins shown to regulate proliferation and cell death, such as Aurora-A, Cyclin D1, and Smad1. The correlation between the stimulation of ODC activity and the absence of AZ as influenced by amino acids is high. Not only do amino acids such as ASN and GLN stimulate ODC while inhibiting AZ synthesis, but also amino acids such as lysine, valine, and ornithine, which inhibit ODC activity, increase the synthesis of AZ. The question remaining to be answered is whether AZ inhibits growth directly or whether it acts by decreasing the availability of polyamines to the dividing cells. In either case, evidence strongly suggests that the regulation of AZ synthesis is the mechanism through which amino acids influence the growth of intestinal mucosa. This brief article reviews the experiments leading to the information presented above. We also present evidence from the literature that AZ acts directly to inhibit cell proliferation and increase the rate of apoptosis. Finally, we discuss future experiments that will determine the role of AZ in the regulation of intestinal mucosal growth by amino acids.     

Enzymatic glycosylation of the topical antibiotic mupirocin

Mupirocin is a commercially available antibiotic that acts on bacterial isoleucyl-tRNA synthetase, thereby inhibiting protein synthesis and preventing bacterial infection. An in vitro glycosylation approach was applied to synthesize glycoside derivatives of mupirocin using different NDP-sugars and glycosyltransferase from Bacillus licheniformis. Ultra pressure liquid chromatography-photo diode array analyses of the reaction mixtures revealed the generation of product peak(s). The results were further supported by high-resolution quadruple time of flight electrospray ionization mass spectrometry analyses. The product purified from the reaction mixture with UDP-D-glucose was subjected to NMR analysis, and the structure was determined to be mupirocin 6-O-β-D-glucoside. Other glycoside analogs of mupirocin were determined based on high-resolution mass analyses. Antibacterial activity assays against Staphylococcus aureus demonstrated complete loss of antibacterial activity after glucosylation of mupirocin at the 6-hydroxyl position.     

Late-Onset Dietary Restriction Modulates Protein Carbonylation and Catalase in Cerebral Hemispheres of Aged Mice

Oxidative stress is an important factor in causing aging and age-related diseases. It is caused by an imbalance between oxidants such as reactive oxygen species (ROS) and antioxidants. Protein oxidation elicited by free radicals may cause protein function disruptions. Protein carbonylation, an irreversible process resulting in loss of function of the modified proteins, is a widely used marker for oxidative stress. In the present study, we have evaluated the levels of protein carbonyls, ROS, and catalase in the cerebral hemispheres of young and aged mice. When aged mice were subjected to a dietary restriction (DR) regimen (alternate days feeding) of 3 months, a significant reduction in the endogenous levels of protein carbonylation as well as ROS and elevation of catalase was observed in their cerebral hemispheres. The present study, thus, demonstrated the antioxidative effects of late-onset DR regimen in the cerebral hemispheres of aged mice which may act as a powerful modulator of age-related neurodegenerative diseases.     

The demography and population genomics of evolutionary transitions to self-fertilization in plants

The evolution of self-fertilization from outcrossing has occurred on numerous occasions in flowering plants. This shift in mating system profoundly influences the morphology, ecology, genetics and evolution of selfing lineages. As a result, there has been sustained interest in understanding the mechanisms driving the evolution of selfing and its environmental context. Recently, patterns of molecular variation have been used to make inferences about the selective mechanisms associated with mating system transitions. However, these inferences can be complicated by the action of linked selection following the transition. Here, using multilocus simulations and comparative molecular data from related selfers and outcrossers, we demonstrate that there is little evidence for strong bottlenecks associated with initial transitions to selfing, and our simulation results cast doubt on whether it is possible to infer the role of bottlenecks associated with reproductive assurance in the evolution of selfing. They indicate that the effects of background selection on the loss of diversity and efficacy of selection occur rapidly following the shift to high selfing. Future comparative studies that integrate explicit ecological and genomic details are necessary for quantifying the independent and joint effects of selection and demography on transitions to selfing and the loss of genetic diversity.     

Glucosylation of Isoflavonoids in Engineered Escherichia coli

A glycosyltransferase, YjiC, from Bacillus licheniformis has been used for the modification of the commercially available isoflavonoids genistein, daidzein, biochanin A and formononetin. The in vitro glycosylation reaction, using UDP-α-D-glucose as a donor for the glucose moiety and aforementioned four acceptor molecules, showed the prominent glycosylation at 4′ and 7 hydroxyl groups, but not at the 5^th hydroxyl group of the A-ring, resulting in the production of genistein 4′-O-β-D-glucoside, genistein 7-O-β-D-glucoside (genistin), genistein 4′,7-O-β-D-diglucoside, biochanin A-7-O-β-D-glucoside (sissotrin), daidzein 4′-O-β-D-glucoside, daidzein 7-O-β-D-glucoside (daidzin), daidzein 4′, 7-O-β-D-diglucoside, and formononetin 7-O-β-D-glucoside (ononin). The structures of all the products were elucidated using high performance liquid chromatography-photo diode array and high resolution quadrupole time-of-flight electrospray ionization mass spectrometry (HR QTOFESI/MS) analysis, and were compared with commercially available standard compounds. Significantly higher bioconversion rates of all four isoflavonoids was observed in both in vitro as well as in vivo bioconversion reactions. The in vivo fermentation of the isoflavonoids by applying engineered E. coli BL21(DE3)/ΔpgiΔzwfΔushA overexpressing phosphoglucomutase (pgm) and glucose 1-phosphate uridyltransferase (galU), along with YjiC, found more than 60% average conversion of 200 μM of supplemented isoflavonoids, without any additional UDP-α-D-glucose added in fermentation medium, which could be very beneficial to large scale industrial production of isoflavonoid glucosides.