Sustainable Use of Bioactive Compounds from Solanum Tuberosum and Brassicaceae Wastes and by-Products for Crop Protection—A Review

Defatted seed meals of oleaginous Brassicaceae, such as Eruca sativa, and potato peel are excellent plant matrices to recover potentially useful biomolecules from industrial processes in a circular strategy perspective aiming at crop protection. These biomolecules, mainly glycoalkaloids and phenols for potato and glucosinolates for Brassicaceae, have been proven to be effective against microbes, fungi, nematodes, insects, and even parasitic plants. Their role in plant protection is overviewed, together with the molecular basis of their synthesis in plant, and the description of their mechanisms of action. Possible genetic and biotechnological strategies are presented to increase their content in plants. Genetic mapping and identification of closely linked molecular markers are useful to identify the loci/genes responsible for their accumulation and transfer them to elite cultivars in breeding programs. Biotechnological approaches can be used to modify their allelic sequence and enhance the accumulation of the bioactive compounds. How the global challenges, such as reducing agri-food waste and increasing sustainability and food safety, could be addressed through bioprotector applications are discussed here.

Suitability of current typing procedures to identify epidemiologically linked human Giardia duodenalis isolates

Background Giardia duodenalis is a leading cause of gastroenteritis worldwide. Humans are mainly infected by two different subtypes, i.e., assemblage A and B. Genotyping is hampered by allelic sequence heterozygosity (ASH) mainly in assemblage B, and by occurrence of mixed infections. Here we assessed the suitability of current genotyping protocols of G. duodenalis for epidemiological applications such as molecular tracing of transmission chains. Methodology/Principal findings Two G. duodenalis isolate collections, from an outpatient tropical medicine clinic and from several primary care laboratories, were characterized by assemblage-specific qPCR (TIF, CATH gene loci) and a common multi locus sequence typing (MLST; TPI, BG, GDH gene loci). Assemblage A isolates were further typed at additional loci (HCMP22547, CID1, RHP26, HCMP6372, DIS3, NEK15411). Of 175/202 (86.6%) patients the G. duodenalis assemblage could be identified: Assemblages A 25/175 (14.3%), B 115/175 (65.7%) and A+B mixed 35/175 (20.0%). By incorporating allelic sequence heterozygosity in the analysis, the three marker MLST correctly identified 6/ 9 (66,7%) and 4/5 (80.0%) consecutive samples from chronic assemblage B infections in the two collections, respectively, and identified a cluster of five independent patients carrying assemblage B parasites of identical MLST type. Extended MLST for assemblage A altogether identified 5/6 (83,3%) consecutive samples from chronic assemblage A infections and 15 novel genotypes. Based on the observed A+B mixed infections it is estimated that only 75% and 50% of assemblage A or B only cases represent single strain infections, respectively. We demonstrate that typing results are consistent with this prediction. Conclusions/Significance Typing of assemblage A and B isolates with resolution for epidemiological applications is possible but requires separate genotyping protocols. The high frequency of multiple infections and their impact on typing results are findings with immediate consequences for result interpretation in this field.

Allelic characterization and protein structure analysis reveals the involvement of splice site mutation for growth habit differences in Lablab purpureus (L.) Sweet

Background Interrelationship between growth habit and flowering played a key role in the domestication history of pulses; however, the actual genes responsible for these traits have not been identified in Indian bean. Determinate growth habit is desirable due to its early flowering, photo-insensitivity, synchronous pod maturity, ease in manual harvesting and short crop duration. The present study aimed to identify, characterize and validate the gene responsible for growth habit by using a candidate gene approach coupled with sequencing, multiple sequence alignment, protein structure prediction and binding pocket analysis. Results Terminal flowering locus was amplified from GPKH 120 (indeterminate) and GNIB-21 (determinate) using the primers designed from PvTFL1y locus of common bean. Gene prediction revealed that the length of the third and fourth exons differed between the two alleles. Allelic sequence comparison indicated a transition from guanine to adenine at the end of the third exon in GNIB 21. This splice site single-nucleotide polymorphism (SNP) was validated in germplasm lines by sequencing. Protein structure analysis indicated involvement of two binding pockets for interaction of terminal flowering locus (TFL) protein with other proteins. Conclusion The splice site SNP present at the end of the third exon of TFL locus is responsible for the transformation of shoot apical meristem into a reproductive fate in the determinate genotype GNIB 21. The splice site SNP leads to absence of 14 amino acids in mutant TFL protein of GNIB 21, rendering the protein non-functional. This deletion disturbed previously reported anion-binding pocket and secondary binding pocket due to displacement of small β-sheet away from an external loop. This finding may enable the modulation of growth habit in Indian bean and other pulse crops through genome editing.

Whole genome sequencing of dog specific assemblages C and D of Giardia duodenalis from single and pooled cysts indicates host associated genes

Giardia duodenalis (Syn. G. intestinalis or G. lamblia) infects over 280 million people each year and numerous animals. G. duodenalis can be subdivided into 8 assemblages with different host specificity. Unculturable assemblages have so far resisted genome sequencing efforts. In this study we isolated single and pooled cysts of assemblage C and D from dog faeces by FACS and sequenced them using multiple displacement amplification and Illumina paired end sequencing. The genomes of assemblages C and D were compared with genomes of assemblages A and B from humans and assemblage E from ruminants and pigs. The genomes obtained from the pooled cysts and from the single cysts were considered complete (>99% marker genes observed) and the allelic sequence heterozygosity (ASH) of assemblage C and D was 0.89% and 0.74%, respectively. Higher than for assemblage B (> 0.43%) and much higher than for assemblages A and E (<0.01%). The flavohemoglobin and 4Fe-4S binding domain family gene involved in O2 and NO detoxification were only present in assemblages A, B and E. Cathepsin-B orthologs were found in all genomes. Six clades of cathepsin-B orthologs contained one gene of each genome, while in three clades not all assemblages were represented. We conclude that whole genome sequencing from a single Giardia cyst results in complete draft genomes making the genomes of unculturable Giardia assemblages accessible. Observed differences between the genomes of assemblage C and D on one hand and the assemblages A, B and E on the other hand are possibly associated with host specificity.

Coalescence and linkage disequilibrium in facultatively sexual diploids

Under neutrality, linkage disequilibrium (LD) results from physically linked sites having non-independent coalescent histories. In obligately sexual organisms, meiotic recombination is the dominant force separating linked variants from one another, and thus in determining the decay of LD with physical distance. In facultatively sexual diploid organisms that principally reproduce clonally, mechanisms of mitotic exchange are expected to become relatively more important in shaping LD. Here we outline mathematical and computational models of a facultative-sex coalescent process that includes meiotic and mitotic recombination, via both crossovers and gene conversion, to determine how LD is affected with facultative sex. We demonstrate that the degree to which LD is broken down by meiotic recombination simply scales with the probability of sex if it is sufficiently high (much greater than 1/N for N the population size). However, with very rare sex (occurring with frequency on the order of 1/N), mitotic gene conversion plays a particularly important and complicated role because it both breaks down associations between sites and removes within-individual diversity. Strong population structure under rare sex leads to lower average LD values than in panmictic populations, due to the influence of low-frequency polymorphisms created by allelic sequence divergence acting in individual subpopulations. These analyses provide information on how to interpret observed LD patterns in facultative sexuals, and determine what genomic forces are likely to shape them.

In silico analysis of Beta-Lactoglobulin gene in some selected mammalian species

This study investigated in silico, the genetic diversity of Beta- Lactoglobulin (?-Lg) and their evolutionary and differentiation within and among selected mammalian species; and also examined the attendant effects of polymorphism on the functionality of the gene. A total of 21 ?-Lg gene sequences with corresponding amino acids belonging to 6 species [cattle (4), buffalo (4), sheep (3), goat (3), pig (3) and horse (4)] were retrieved from GenBank (www.ncbi.nlm.nih.gov). All sequences were trimmed to equal length (500bp) corresponding to the same region. Sequences? alignment, translation and comparison were done with ClustalW using IUB substitution matrix, gap open penalty of 15 and gap extension penalty of 6.66. The alignment revealed high polymorphism of sequences among extant species. The Dxy inferred using pdistance revealed that sheep and goat had the lowest distance of 0.05 with a maximum distance of 0.65 between goat and horse. The hypothesis of strict neutrality (dN = dS) was rejected for all extant species as allelic sequence evolution was driven by both purifying and positive selection. Only those of pig and buffalo were driven by positive selection. In-silico functional analysis of non-synonymous mutations using PANTHER revealed that, all the 12 amino acid substitutions (10 in cattle and 2 in sheep) did not impair protein function. The Neighbour-Joining phylogeny revealed trans-species evolution, but a species-wise phylogeny was obtained for UPGMA with consensus sequences. Thus, all probed SNPs from this study have no deleterious effect and can be tolerated by breeders when selecting stocks for milk improvement.