Immobilized Baliospermum montanum hydroxynitrile lyase catalyzed synthesis of chiral cyanohydrins

Hydroxynitrile lyase (HNL) catalyzed enantioselective CC bond formation is an efficient approach to synthesize chiral cyanohydrins which are important building blocks in the synthesis of a number of fine chemicals, agrochemicals and pharmaceuticals. Immobilization of HNL is known to provide robustness, reusability and in some cases also enhances activity and selectivity.We optimized the preparation of immobilization of Baliospermium montanum HNL (BmHNL) by cross linking enzyme aggregate (CLEA) method and characterized it by SEM. Optimization of biocatalytic parameters was performed to obtain highest % conversion and ee of (S)-mandelonitrile from benzaldehyde using CLEA-BmHNL. The optimized reaction parameters were: 20 min of reaction time, 7 U of CLEA-BmHNL, 1.2 mM substrate, and 300 mM citrate buffer pH 4.2, that synthesized (S)-mandelonitrile in ∼99% ee and ∼60% conversion. Addition of organic solvent in CLEA-BmHNL biocatalysis did not improve in % ee or conversion of product unlike other CLEA-HNLs. CLEA-BmHNL could be successfully reused for eight consecutive cycles without loss of conversion or product formation and five cycles with a little loss in enantioselectivity. Eleven different chiral cyanohydrins were synthesized under optimal biocatalytic conditions in up to 99% ee and 59% conversion, however the % conversion and ee varied for different products. CLEA-BmHNL has improved the enantioselectivity of (S)-mandelonitrile synthesis compared to the use of purified BmHNL. Nine aldehydes not tested earlier with BmHNL were converted into their corresponding (S)-cyanohydrins for the first time using CLEA-BmHNL. Among the eleven (S)-cyanohydrins syntheses reported here, eight of them have not been synthesized by any CLEA-HNL. Overall, this study showed preparation, characterization of a stable, robust and recyclable biocatalyst i.e. CLEA-BmHNL and its biocatalytic application in the synthesis of different (S)-aromatic cyanohydrins.     

A study on increasing enzymatic stability and activity of Baliospermum montanum hydroxynitrile lyase in biocatalysis

HNL catalysis is usually carried out in a biphasic solvent and at low pH to suppress the non-enzymatic synthesis of racemic cyanohydrins. However, enzyme stability under these conditions remain a challenge. We have investigated the effect of different biocatalytic parameters, i.e., pH, temperature, buffer concentrations, presence of stabilizers, organic solvents, and chemical additives on the stability of Baliospermum montanum hydroxynitrile lyase (BmHNL). Unexpectedly, glycerol (50 mg/mL) added BmHNL biocatalysis had produced >99% of (S)-mandelonitrile from benzaldehyde, while without glycerol it is 54% ee. Similarly, BmHNL had converted 3-phenoxy benzaldehyde and 3,5-dimethoxy benzaldehyde, to their corresponding cyanohydrins in the presence of glycerol. Among the different stabilizers added to BmHNL at low pH, 400 mg/mL of sucrose had increased enzyme’s half-life more than fivefold. BmHNL’s stability study showed half-lives of 554, 686, and 690 h at its optimum pH 5.5, temperature 20 °C, buffer concentration, i.e., 100 mM citrate-phosphate pH 5.5. Addition of benzaldehyde as inhibitor, chemical additives, and the presence of organic solvents have decreased both the stability and activity of BmHNL, compared to their absence. Secondary structural study by CD-spectrophotometer showed that BmHNL’s structure is least affected in the presence of different organic solvents and temperatures.     

Hydroxynitrile lyases from prunus seeds in the preparation of cyanohydrins

The hydroxynitrile lyase (HNL) activity of nine defatted Prunus seeds was compared for catalyzing the addition of HCN to aromatic, heteroaromatic and α,β-unsaturated aldehydes. Although the conversion and enantiomeric excess (ee) of the corresponding cyanohydrins were both influenced by the HNL source and the chemical structure of the aldehyde, Prunus HNLs were all suitable for the enantioselective preparation of cyanohydrins.     

Structural and functional analysis of hydroxynitrile lyase from Baliospermum montanum with crystal structure,molecular dynamics and enzyme kinetics

Hydroxynitrile lyases (HNLs) catalyze degradation of cyanohydrins to hydrogen cyanide and the corresponding ketone or aldehyde. HNLs can also catalyze the reverse reaction, i.e., synthesis of cyanohydrins. Although several crystal structures of S-selective hydroxynitrile lyases (S-HNLs) have been reported, it remains unknown whether and how dynamics at the active site of S-HNLs influence their broad substrate specificity and affinity. In this study, we analyzed the structure, dynamics and function of S-HNL from Baliospermum montanum (BmHNL), which has an α/β hydrolase fold. Two crystal structures of BmHNL, apo1 and apo2, were determined at 2.55 and 1.9 Å, respectively. Structural comparison between BmHNL (apo2) and S-HNL from Hevea brasiliensis with (S)-mandelonitrile bound to the active site revealed that hydrophobic residues at the entrance region of BmHNL formed hydrophobic interactions with the benzene ring of the substrate. The flexible structures of these hydrophobic residues were confirmed by a 15 ns molecular dynamics simulation. This flexibility regulated the size of the active site cavity, enabling binding of various substrates to BmHNL. The high affinity of BmHNL toward substrates containing a benzene ring was also confirmed by comparing the kinetics of BmHNL and S-HNL from Manihot esculenta. Taken together, the results indicated that the flexibility and placement of the residues are important for the broad substrate specificity of S-HNLs.     

Screening hydroxynitrile lyases for (R)-pantolactone synthesis

The application of (R)-hydroxynitrile lyases ((R)-HNLs) enables a simple chemo-enzymatic approach towards (R)-pantolactone synthesis. For the first time, several new recombinant almond (R)-HNL isoenzymes were compared with native HNLs from different Prunus species with respect to cyanohydrin formation from hydroxypivalaldehyde providing the chiral key precursor in HNL based (R)-pantolactone synthesis. Recombinant PaHNL5 (R-selective hydroxynitrile lyase, isoenzyme 5, from Prunus amygdalus) surpasses all other tested natural and recombinant HNL variants. At low pH even very low amounts of crude enzyme catalysed stereoselective hydroxypivalaldehyde cyanohydrin formation in water based reaction systems.     

<Emphasis Type="Italic">Prunus</Emphasis> microsatellite marker transferability across rosaceous crops

A total of 145 microsatellite primer pairs from Prunus DNA sequences were studied for transferability in a set of eight cultivars from nine rosaceous species (almond, peach, apricot, Japanese plum, European plum, cherry, apple, pear, and strawberry), 25 each of almond genomic, peach genomic, peach expressed sequence tags (EST), and Japanese plum genomic, 22 of almond EST, and 23 of apricot (13 EST and 10 genomic), all known to produce single-locus and polymorphic simple-sequence repeats in the species where they were developed. Most primer pairs (83.6%) amplified bands of the expected size range in other Prunus. Transferability, i.e., the proportion of microsatellites that amplified and were polymorphic, was also high in Prunus (63.9%). Almond and Japanese plum were the most variable among the diploid species (all but the hexaploid European plum) and peach the least polymorphic. Thirty-one microsatellites amplified and were polymorphic in all Prunus species studied, 12 of which, covering its whole genome, are proposed as the “universal Prunus set”. In contrast, only 16.3% were transferable in species of other Rosaceae genera (apple, pear, and strawberry). Polymorphic Prunus microsatellites also detected lower levels of variability in the non-congeneric species. No significant differences were detected in transferability and the ability to detect variability between microsatellites of EST and genomic origin.     

Phylogenetics of Eurasian plums, <Emphasis Type="Italic">Prunus</Emphasis> L. section <Emphasis Type="Italic">Prunus</Emphasis> (Rosaceae), according to coding and non-coding chloroplast DNA sequences

The genus Prunus contains the subgenus Prunus incorporating the European plums (section Prunus), the North American plums (section Prunocerasus) and the apricots (section Armeniaca). In section Prunus, there are approximately 20 species, which occur in three levels of ploidy, diploid ( 2n = 2x = 16 ) \left( {2n = 2x = 16} \right) , tetraploid ( 2n = 4x = 32 ) \left( {2n = 4x = 32} \right) and hexaploid ( 2n = 6x = 48 ) \left( {2n = 6x = 48} \right) . Despite a clear distinction between section Prunus and the other sections, phylogenetic relationships between species within the section are unclear. We performed a phylogenetic analysis on members of the section Prunus and three outgroup species using sequence data from four single-copy phylogenetically informative chloroplast DNA regions (atpB-rbcL, matK, rpl16, and trnL-trnF). After alignment, the analysed regions totalled 4,696 bp of sequence, containing 68 parsimony-informative sites and 14 parsimony-informative indels. Data were analysed using both maximum parsimony and Bayesian likelihood and phylogenetic trees were reconstructed. The analyses recovered trees with congruent topologies and similar levels of statistical support for relationships between taxa. They confirmed that species belonging to section Prunus form a monophyletic clade within Prunus. The section is resolved into four well-supported clades, which correspond to the geographical distribution of the species. The hexaploid species could not be resolved into distinct species clades but formed a well-supported group separate from the tetraploid species, highlighting the distinct evolutionary origins of the different polyploid groups. The close relationship between the hexaploids and Prunus divaricata, Prunus cerasifera and Prunus ursina indicates the former may have derived from an ancestor of P. cerasifera and its allies.     

Characterization of a New (R)-Hydroxynitrile Lyase from the Japanese Apricot Prunus mume and cDNA Cloning and Secretory Expression of One of the Isozymes in Pichia pastoris

PmHNL, a hydroxynitrile lyase from Japanese apricot ume (Prunus mume) seed was purified to homogeneity by ammonium sulfate fractionation and chromatographic steps. The purified enzyme was a monomer with molecular mass of 58 kDa. It was a flavoprotein similar to other hydroxynitrile lyases of the Rosaceae family. It was active over a broad temperature, and pH range. The N-terminal amino acid sequence (20 amino acids) was identical with that of the enzyme from almond (Prunus dulcis). Based on the N-terminal sequence of the purified enzyme and the conserved amino acid sequences of the enzymes from Pr. dulcis, inverse PCR method was used for cloning of a putative PmHNL (PmHNL2) gene from a Pr. mume seedling. Then the cDNA for the enzyme was cloned. The deduced amino acid sequence was found to be highly similar (95%) to that of an enzyme from Pr. serotina, isozyme 2. The recombinant Pichia pastoris transformed with the PmHNL2 gene secreted an active enzyme in glycosylated form.     

Biotechnological approaches for improvement and conservation of Prunus species

Biotechnology has contributed to improvement and conservation of Prunus species. Biotechnological approaches involving in vitro tissue culture, genetic transformation, molecular marker development and cryopreservation were applied to various Prunus species. This report provides an overview of biotechnological research on Prunus species, with an emphasis on ornamental Prunus.     

Phylogenetic analysis of morphology in Prunus reveals extensive homoplasy

Prunus is a large and economically important genus with considerable morphological variation. The evolution of vegetative and reproductive characters are examined here by parsimony reconstruction on trees obtained from data of ITS, trnL-trnF, trnS-trnG, and 25 morphological characters of 37 species of Prunus and representatives of eight other genera of Rosaceae. Prunus grayana is supported as the sister species to the rest of Prunus and the common ancestor of Prunus is reconstructed as having deciduous and serrated leaves, leafy racemes and fruit with well-developed pericarp. All diagnostic characters used in classification of the raceme-bearing species show some degree of convergent evolution and do not reflect phylogenetic relatedness. Some character states, such as evergreen foliage and entire leaf margin, are likely adaptations to environments with higher humidity and mean temperature. However, these hypotheses need to be tested by including species formerly classified in genus Pygeum, which were not available for this study. A clade consisting of subgenera Prunus, Amygdalus, Emplectocladus and section Microcerasus (formerly in subgenus Cerasus) is characterized by having axillary buds organized in groups of three, two of which give rise to flowers or inflorescences and one to a vegetative shoot. Fruits with thin pericarps are common in Prunus but they arose more than once independently. Dry fruits also evolved more than once, and only in species of Prunus living in arid environments, suggesting that this feature is another example of adaptation. Maddenia hypoleuca is nested within Prunus and the morphological characters used to segregate it from Prunus have been misinterpreted or are also found in species of Prunus previously classified in genus Pygeum.     

Construction of an intra-specific sweet cherry (<Emphasis Type="Italic">Prunus avium</Emphasis> L.) genetic linkage map and synteny analysis with the <Emphasis Type="Italic">Prunus</Emphasis> reference map

Linkage maps of the sweet cherry cultivar ‘Emperor Francis’ (EF) and the wild forest cherry ‘New York 54’ (NY) were constructed using primarily simple sequence repeat (SSR) markers and gene-derived markers with known positions on the Prunus reference map. The success rate for identifying SSR markers that could be placed on either the EF or NY maps was only 26% due to two factors: a reduced transferability of other Prunus-species-derived markers and a low level of polymorphism in the mapping parents. To increase marker density, we developed four cleaved amplified polymorphic sequence markers (CAPS), 19 derived CAPS markers, and four insertion–deletion markers for cherry based on 101 Prunus expressed sequence tags. In addition, four gene-derived markers representing orthologs of a tomato vacuolar invertase and fruit size gene and two sour cherry sorbitol transporters were developed. To complete the linkage analysis, 61 amplified fragment length polymorphism and seven sequence-related amplified polymorphism markers were also used for map construction. This analysis resulted in the expected eight linkage groups for both parents. The EF and NY maps were 711.1 cM and 565.8 cM, respectively, with the average distance between markers of 4.94 cM and 6.22 cM. A total of 82 shared markers between the EF and NY maps and the Prunus reference map showed that the majority of the marker orders were the same with the Prunus reference map suggesting that the cherry genome is colinear with that of the other diploid Prunus species. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Looking into flowering time in almond (Prunus dulcis (Mill) D. A. Webb): the candidate gene approach

Blooming time is one of the most important agronomic traits in almond. Biochemical and molecular events underlying flowering regulation must be understood before methods to stimulate late flowering can be developed. Attempts to elucidate the genetic control of this process have led to the identification of a major gene (Lb) and quantitative trait loci (QTLs) linked to observed phenotypic differences, but although this gene and these QTLs have been placed on the Prunus reference genetic map, their sequences and specific functions remain unknown. The aim of our investigation was to associate these loci with known genes using a candidate gene approach. Two almond cDNAs and eight Prunus expressed sequence tags were selected as candidate genes (CGs) since their sequences were highly identical to those of flowering regulatory genes characterized in other species. The CGs were amplified from both parental lines of the mapping population using specific primers. Sequence comparison revealed DNA polymorphisms between the parental lines, mainly of the single nucleotide type. Polymorphisms were used to develop co-dominant cleaved amplified polymorphic sequence markers or length polymorphisms based on insertion/deletion events for mapping the candidate genes on the Prunus reference map. Ten candidate genes were assigned to six linkage groups in the Prunus genome. The positions of two of these were compatible with the regions where two QTLs for blooming time were detected. One additional candidate was localized close to the position of the Evergrowing gene, which determines a non-deciduous behaviour in peach.     

Enzymatic hydrolysis of cyanohydrins with recombinant nitrile hydratase and amidase from hodococcus erythropolis

Nitrile hydratase and amidase from Rhodococcus erythropolis CIMB11540 were both cloned and expressed in Escherichia coli.Crude cell free extracts were used for the hydrolysis of different aromatic cyanohydrins. Nitrile hydratase expression was increased up to 5-fold by redesign of the expression cassette. The recombinant enzymes were successfully used for the conversion of several cyanohydrins to the corresponding α-hydroxy amides and acids while retaining enantiopurity.     

Development of a new SSR-based linkage map in apricot and analysis of synteny with existing Prunus maps

Linkage maps of the apricot accessions ‘Lito’ and ‘BO 81604311’ were constructed using a total of 185 simple sequence repeat (SSR) markers sampled from those isolated in peach, almond, apricot and cherry; 74 were derived from a new apricot genomic library enriched for AG/CT microsatellite repeats (UDAp series), and in total, 98 had never been mapped in Prunus before. Eight linkage groups putatively corresponding to the eight haploid apricot chromosomes were identified for each parent. The two maps were 504 and 620 cM long, respectively, with 96 anchor markers showing a complete co-linearity between the two genomes. As few as three gaps larger than 15 cM were present in ‘Lito’ and six in the male parent; the maps align well with all the available SSR-based Prunus maps through the many common anchor loci. Only occasionally inverted positions between adjacent markers were found, and this can be explained by the small size of cross populations analysed in these Prunus maps and in those reported in literature. The newly developed apricot SSRs will help saturating the existing Prunus maps and will extend the choice of markers in the development of genetic maps for new breeding populations.     

Trans-specific <Emphasis Type="Italic">S</Emphasis>-RNase and SFB alleles in <Emphasis Type="Italic">Prunus</Emphasis> self-incompatibility haplotypes

Self-incompatibility in the genus Prunus is controlled by two genes at the S-locus, S-RNase and SFB. Both genes exhibit the high polymorphism and high sequence diversity characteristic of plant self-incompatibility systems. Deduced polypeptide sequences of three myrobalan and three domestic plum S-RNases showed over 97% identity with S-RNases from other Prunus species, including almond, sweet cherry, Japanese apricot and Japanese plum. The second intron, which is generally highly polymorphic between alleles was also remarkably well conserved within these S-allele pairs. Degenerate consensus primers were developed and used to amplify and sequence the co-adapted polymorphic SFB alleles. Sequence comparisons also indicated high degrees of polypeptide sequence identity between three myrobalan and the three domestic plum SFB alleles and the corresponding Prunus SFB alleles. We discuss these trans-specific allele identities in terms of S-allele function, evolution of new allele specificities and Prunus taxonomy and speciation. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Characterization of two bacterial hydroxynitrile lyases with high similarity to cupin superfamily proteins

Hydroxynitrile lyases (HNLs) catalyze the cleavage of cyanohydrins. In the reverse reaction, they catalyze the formation of carbon-carbon bonds by enantioselective condensation of hydrocyanic acid with carbonyls. In this study, we describe two proteins from endophytic bacteria that display activity in the cleavage and the synthesis reaction of (R)-mandelonitrile with up to 74% conversion of benzaldehyde (enantiopreference ee 89%). Both showed high similarity to proteins of the cupin superfamily which so far were not known to exhibit HNL activity.     

New set of microsatellite loci isolated in apricot

We report 99 simple sequence repeats (SSRs) newly isolated from an apricot (Prunus armeniaca L.) genomic library enriched for AG/CT repeats. Twenty SSRs were screened for their polymorphism in 16 apricot cultivars. The number of alleles ranged from two to nine, whereas the expected heterozygosity (H_E) ranged from 0.26 to 0.82. The same SSRs showed also an appreciable transportability across different Prunus species, such as peach, nectarine, almond, European plum, Japanese plum, sweet cherry and sour cherry, with 20% of primers giving successful amplifications in all Prunus species assayed. None gave amplification in apple.     

Merging Maddenia with the morphologically diverse Prunus (Rosaceae)

Maddenia (Rosaceae) has been distinguished from Prunus on the basis of its tepaloid perianth and one‐ to two‐carpellate gynoecium. These distinctive morphological traits nonetheless overlap with several Prunus spp. Maddenia has previously been shown to be nested within Prunus, more specifically within a clade containing members of subgenera Laurocerasus and Padus, but its phylogenetic position within that clade has not been defined precisely. This study clarifies the position of Maddenia within Prunus through phylogenetic analyses of nuclear ribosomal internal transcribed spacer (ITS) and plastid ndhF sequences, with an expanded sampling of tropical species of subgenus Laurocerasus and the inclusion of three Maddenia spp. The monophyly of Maddenia is supported by both the ITS and ndhF analyses, but both datasets support the inclusion of Maddenia in Prunus. All trees from the ITS analysis and some trees from the ndhF analysis also support a close alliance of Maddenia with a clade comprising temperate species of subgenera Laurocerasus and Padus. On the basis of these results, all recognized species of Maddenia are herein formally transferred to Prunus, which requires four new combinations and one new name: Prunus fujianensis (Y.T.Chang) J.Wen, comb. nov. ; Prunus himalayana J.Wen, nom. nov. ; Prunus hypoleuca (Koehne) J.Wen, comb. nov. ; Prunus hypoxantha (Koehne) J.Wen, comb. nov. ; and Prunus incisoserrata (T.T.Yü & T.C.Ku) J.Wen, comb. nov. © 2010 The Linnean Society of London, Botanical Journal of the Linnean Society, 2010, 164 , 236–245.     

Spatial heterogeneity in post-dispersal predation on Prunus and Uvularia seeds

Summary We investigated effects of seed density, distance from parent, and habitat (woods, open field) on post-dispersal predation risk (chiefly by rodents) for seeds of Prunus virginiana (Rosaceae). Additional study of the habitat effect (woods, open field, treefall gap) was made with seeds of Prunus avium (Rosaceae) and Uvularia grandiflora (Liliaceae). Density of Prunus seeds (range 2–40 seeds/group) did not affect predation risk for individual seeds. Distance from parent plants did influence predation risk, which was greatest directly beneath parents. This distance effect primarily comprised a sharp drop in risk within 2 m of parents, a distance too small to generate a spacing rule for conspecifics.We found that habitat strongly influenced predation intensity. Rates of removal of Prunus seeds were higher in woods than in open fields, except when overall predation intensity was very low and no pattern could be discerned. Prunus seed removal rates were higher in closed woods than in treefall gaps. Consequently, a Prunus seed will more likely escape predation if dispersed to an open site. In contrast, Uvularia seed removal rates were higher in open fields than in woods but did not differ between closed woods and tree-fall gaps.Predation intensity was spatially patchy between and within experimental arrays, but was consistent over time at some specific points in space, possibly reflecting home ranges of seed predators.     

Recent advances and prospects in Prunus virology

The stone fruit genus Prunus, within the family Rosaceae, comprises more than 230 species, some of which have great importance or value as ornamental or fruit crops. Prunus are affected by numerous viruses and viroids linked to the vegetative propagation practices in many of the cultivated species. To date, 44 viruses and three viroids have been described in the 9 main cultivated Prunus species. Seven of these viruses and one viroid have been identified in Prunus hosts within the last 5 years. This work addresses recent advances and prospects in the study of viruses and viroids affecting Prunus species, mostly concerning the detection and characterisation of the agents involved, pathogenesis analysis and the search for new control tools. New sequencing technologies are quickly reshaping the way we can identify and characterise new plant viruses and isolates. Specific efforts aimed at virus identification or data mining of high‐throughput sequencing data generated for plant genomics‐oriented purposes can efficiently reveal the presence of known or novel viruses. These technologies have also been used to gain a deeper knowledge of the pathogenesis mechanisms at the gene and miRNA expression level that underlie the interactions between Prunus spp. and their main viruses and viroids. New biotechnological control tools include the transfer of resistance by grafting, the use of new sources of resistance and the development of gene silencing strategies using genetic transformation. In addition, the application of next generation sequencing and genome editing techniques will contribute to improving our knowledge of virus–host interactions and the mechanisms of resistance. This should be of great interest in the search to obtain new Prunus cultivars capable of dealing both with known viruses and viroids and with those that are yet to be discovered in the uncertain scenario of climate change.