Kunitz-type protease inhibitors group B from Solanum palustre

Five Kunitz protease inhibitor group B genes were isolated from the genome of the diploid non-tuber-forming potato species Solanum palustre. Three of five new genes share 99% identity to the published KPI-B genes from various cultivated potato accessions, while others exhibit 96% identity. Spls-KPI-B2 and Spls-KPI-B4 proteins contain unique substitutions of the most conserved residues usually involved to trypsin and chymotrypsin-specific binding sites of Kunitz-type protease inhibitor (KPI)-B, respectively. To test the inhibition of trypsin and chymotrypsin by Spls-KPI proteins, five of them were produced in E. coli purified using a Ni-sepharose resin and ion-exchange chromatography. All recombinant Spls-KPI-B inhibited trypsin; K(i) values ranged from 84.8 (Spls-KPI-B4), 345.5 (Spls-KPI-B1), and 1310.6 nM (Spls-KPI-B2) to 3883.5 (Spls-KPI-B5) and 8370 nM (Spls-KPI-B3). In addition, Spls-KPI-B1 and Spls-KPI-B4 inhibited chymotrypsin. These data suggest that regardless of substitutions of key active-center residues both Spls-KPI-B4 and Spls-KPI-B1 are functional trypsin-chymotrypsin inhibitors.     

Heterologous expression, purification, and properties of a potato protein inhibitor of serine proteinases

The gene PKPI-B10 [AF536175] encoding in potato (Solanum tuberosum L., cv. Istrinskii) a Kunitz-type protein inhibitor of proteinases (PKPI) has been cloned into the pET23a vector and then expressed in Escherichia coli. The recombinant protein PKPI-B10 obtained as inclusion bodies was denatured, separated from admixtures by ion-exchange fast protein liquid chromatography (FPLC) on MonoQ under denaturing conditions, and renatured. The native protein was additionally purified by ion-exchange FPLC on DEAE-Toyopearl. The PKPI-B10 protein effectively inhibits the activity of trypsin, significantly weaker suppresses the activity of chymotrypsin, and has no effect on other serine proteinases: human leukocyte elastase, subtilisin Carlsberg, and proteinase K, and also the plant cysteine proteinase papain.     

High-Throughput Sequencing for the Authentication of Food Products: Problems and Perspectives

The quality of food products is one of the key factors affecting health, life expectancy, and work capacity. An important quality parameter is compliance with the claimed composition, the violation of which can lead to negative repercussion for purchasers which is a risk of allergic reactions and toxic and other side effects. To control the composition in most cases, organoleptic, macro- and microscopic, analytical chemistry methods are used. Molecular methods based on amplification and fluorescence detection of marker DNA fragments, as well as approaches based on mass spectrometry, are also employed. However, owing to certain limitations, such as insufficient sensitivity and incompleteness of the databases used, these methods often do not allow for an accurate analysis of multicomponent mixtures. At present, this problem becomes more urgent because of the rapid development of processing technologies of raw ingredients for the food industry, as well as the globalization of food markets, which leads to the need for development of new approaches to solve this problem. An important addition to the existing methods can become high-throughput sequencing technologies (so-called new generation sequencing, NGS), which allow fast and cheap determination of hundreds of millions of DNA fragments. In this review, the possibilities and prospects of their use for controlling the composition of food products are considered.     

Impact of recombination on polymorphism of genes encoding Kunitz-type protease inhibitors in the genus Solanum

Background

The group of Kunitz-type protease inhibitors (KPI) from potato is encoded by a polymorphic family of multiple allelic and non-allelic genes. The previous explanations of the KPI variability were based on the hypothesis of random mutagenesis as a key factor of KPI polymorphism.

Results

KPI-A genes from the genomes of Solanum tuberosum cv. Istrinskii and the wild species Solanum palustre were amplified by PCR with subsequent cloning in plasmids. True KPI sequences were derived from comparison of the cloned copies. “Hot spots” of recombination in KPI genes were independently identified by DnaSP 4.0 and TOPALi v2.5 software.The KPI-A sequence from potato cv. Istrinskii was found to be 100% identical to the gene from Solanum nigrum. This fact illustrates a high degree of similarity of KPI genes in the genus Solanum. Pairwise comparison of KPI A and B genes unambiguously showed a non-uniform extent of polymorphism at different nt positions. Moreover, the occurrence of substitutions was not random along the strand. Taken together, these facts contradict the traditional hypothesis of random mutagenesis as a principal source of KPI gene polymorphism. The experimentally found mosaic structure of KPI genes in both plants studied is consistent with the hypothesis suggesting recombination of ancestral genes. The same mechanism was proposed earlier for other resistance-conferring genes in the nightshade family (Solanaceae).Based on the data obtained, we searched for potential motifs of site-specific binding with plant DNA recombinases.During this work, we analyzed the sequencing data reported by the Potato Genome Sequencing Consortium (PGSC), 2011 and found considerable inconsistence of their data concerning the number, location, and orientation of KPI genes of groups A and B.

Conclusions

The key role of recombination rather than random point mutagenesis in KPI polymorphism was demonstrated for the first time.     

Cloning of polygalacturonase inhibitor protein genes from Solanum brevidens Fill

New data were obtained for the Solanum brevidens Fill. nucleotide sequences coding for polygalacturonase inhibitor proteins (PGIPs), which are involved in plant defense against phytopathogenic fungi. Highly degenerate primers directed to the conserved regions of the known PGIP genes of tomato, kiwi, apple, carrot, and grape were used to clone four pgip genes and one pseudogene from the genome of S. brevidens, a species that is closely related to cultivated potato, forms no tubers, is highly resistant to phytopathogens, and is often employed in potato breeding. The sequenced part of the coding region of the new genes is 924 bp and codes for a protein of 308 amino acid residues (without the leader peptide). The genes were designated as pgipSbr1(1), pgipSbr1 (2). pgipSbr2, pgipSbr3, and pgipSbr4. The amino acid sequences of the S. brevidens PGIPs have 90.9-99.4% identity to each other and 94% identity to PGIP of Lycopersicon esculentum Mill., another member of the family Solanaceae. The amino acid residues differing between S. brevidens PGIPs were assumed to determine the selectivity of interactions with particular polyglucuronases of phytopathogenic fungi.     

Comparative analysis of inverted repeats of polypod fern (Polypodiales) plastomes reveals two hypervariable regions

Background

Ferns are large and underexplored group of vascular plants (~ 11 thousands species). The genomic data available by now include low coverage nuclear genomes sequences and partial sequences of mitochondrial genomes for six species and several plastid genomes.

Results

We characterized plastid genomes of three species of Dryopteris, which is one of the largest fern genera, using sequencing of chloroplast DNA enriched samples and performed comparative analysis with available plastomes of Polypodiales, the most species-rich group of ferns. We also sequenced the plastome of Adianthum hispidulum (Pteridaceae). Unexpectedly, we found high variability in the IR region, including duplication of rrn16 in D. blanfordii, complete loss of trnI-GAU in D. filix-mas, its pseudogenization due to the loss of an exon in D. blanfordii. Analysis of previously reported plastomes of Polypodiales demonstrated that Woodwardia unigemmata and Lepisorus clathratus have unusual insertions in the IR region. The sequence of these inserted regions has high similarity to several LSC fragments of ferns outside of Polypodiales and to spacer between tRNA-CGA and tRNA-TTT genes of mitochondrial genome of Asplenium nidus. We suggest that this reflects the ancient DNA transfer from mitochondrial to plastid genome occurred in a common ancestor of ferns. We determined the marked conservation of gene content and relative evolution rate of genes and intergenic spacers in the IRs of Polypodiales. Faster evolution of the four intergenic regions had been demonstrated (trnA- orf42, rrn16-rps12, rps7-psbA and ycf2-trnN).

Conclusions

IRs of Polypodiales plastomes are dynamic, driven by such events as gene loss, duplication and putative lateral transfer from mitochondria.

     

Polymorphism of the KPI-A gene sequence in the potato subgenera Potatoe (Sect. Petota, Esolonifera, and Lycopersicum) and Solanum

Group A Kunitz-type protease inhibitors (KPI-A) are involved in protecting potato plants from microorganisms and pests. While the nucleotide sequence is known for many KPI-A genes of various potato cultivars (Solanum tuberosum subsp. tuberosum) and a few genes of tomato (Solanum lycopersicum), there are no data on their allelic diversity in other species of the genus Solanum. KPI-A fragments were cloned, amplified, sequenced, and analyzed from plants of the subgenera Potatoe sect. Petota (five genes from S. tuberosum ssp. andigenum and two genes from S. stoloniferum) and Solanum (five genes from S. nugrum), and their consensus sequences were established. An identity of 97–100% was observed among these sequences and the KPI-A sequences of the sections Petota (cultivated potato Solanum tuberosum ssp. tuberosum) and Etuberosum (S. palustre) The interspecific variation of KPI-A did not exceed its intraspecific variation for all but one species (S. lycopersicum). The distribution of highly variable and conserved sequences in the mature protein-coding region was the same in all of the above species. The same primers failed to amplify the homologous genes from Solanum dulcamara, S. lycopersicum, and Mandragora officinarum. Phylogenetic analysis of the KPI-A sequences showed that S. lycopersicum clustered separately from all of the other species examined, that S. nigrum clustered together with species of the sections Etuberosum and Petota, and that these species produced no species-specific clusters. Although S. nigrum is resistant to all known races of the oomycete Phytophthora infestans, which causes one of the most economically important diseases of Solanaceae, the amino acid sequences encoded by S. nigrum KPI-A differed slightly, if at all, from their counterparts of cultivated potato, which is susceptible to P. infestans infection.     

Cloning of polygalacturonase inhibitor protein genes from Solanum brevidens Fill.

New data were obtained for the Solanum brevidens Fill. nucleotide sequences coding for polygalacturonase inhibitor proteins (PGIPs), which are involved in plant defense against phytopathogenic fungi. Highly degenerate primers directed to the conserved regions of the known PGIP genes of tomato, kiwi, apple, carrot, and grape were used to clone four pgip genes and one pseudogene from the genome of S. brevidens, a species that is closely related to cultivated potato, forms no tubers, is highly resistant to phytopathogens, and is often employed in potato breeding. The sequenced part of the coding region of the new genes is 924 bp and codes for a protein of 308 amino acid residues (without the leader peptide). The genes were designated as pgipSbr1(1), pgipSbr1(2), pgipSbr2, pgipSbr3, and pgipSbr4. The amino acid sequences of the S. brevidens PGIPs have 90.9–99.4% identity to each other and 94% identity to PGIP of Lycopersicon esculentum Mill., another member of the family Solanaceae. The amino acid residues differing between S. brevidens PGIPs were assumed to determine the selectivity of interactions with particular polyglucuronases of phytopathogenic fungi.