Phytochemical characteristics of some plants of Northern Mongolia

The article presents the results of determining the content of pectin substances, organic acids and freesugars in 7 species (8 samples) of plants collected in the steppe regions of Northern Mongolia. These are: Armeniaca sibirica(L.) Lam. – siberian apricot, leaves; Artemisia adamsii Bess. – Adams wormwood, aboveground part; Betula fusca Pallasex Georgi - brown birch, leaves; Iris lactea Pallas, milky white iris, leaves; Polygonatum (Aconogonon) divaricatum L. –spreading knotweed (battering ram), leaves and flowers; Thermopsis dahurica Czefr. – Daurian thermopsis, abovegroundpart; Veronica incana L. – gray-haired Veronica, aboveground part. The studied species comprise a significant amountof pectin substances, citric, acetic, lactic and other organic acids, as well as free sugars: glucose, fructose, sucrose. Thequantitative content of these substances has been determined.

Genome-wide Identification and Expression Analysis of NAC Transcription Factor Family Genes during Fruit and Kernel Development in Siberian Apricot

The NAC (NAM, ATAF1/2, and CUC2) family is a group of plant-specific transcription factors that have vital roles in the growth and development of plants, and especially in fruit and kernel development. This study aimed to identify members of the NAC gene (PsNACs) family and investigate their functions in siberian apricot (Prunus sibirica). A total of 102 predicted PsNAC proteins (PsNACs) were divided into 14 clades and the genes were mapped to the eight chromosomes in siberian apricot. The PsNACs of the same clade had similar structures. A synteny analysis showed that the PsNACs had close relationships with the NAC genes of japanese apricot (Prunus mume). An expression pattern analysis of the PsNACs revealed many differences in various tissues and at different stages of fruit and kernel development. All eight PsNACs in clade XI have crucial roles in fruit and kernel development. Seven PsNACs (PsNACs 18, 64, 23, 33, 9, 4, and 50) in clades I, III, VI, VII, and XIII are related to fruit development. Eight PsNACs (PsNACs 6, 13, 46, 51, 41, 67, 37, and 59) in clades I, II, V, VIII, and XIII are involved in fruit ripening. Five PsNACs (PsNACs 6, 94, 41, 32, and 17) in clades I, IV, V, VII, and XI regulated the rapid growth of the kernel. Four PsNACs (PsNACs 50, 4, 67, and 84) in clades I, III, V, and XIII affected the hardening of the kernel. Four PsNACs (PsNACs 17, 82, 13, and 51) in clades II, XI, and IX acted on kernel maturation. We have characterized the NAC genes in siberian apricot during this study. Our results will provide resources for future research of the biological roles of PsNACs in fruit and kernel development in siberian apricot.

Artemisia gmelinii Web. ex Stechm. within the Buryatian flora: phytocenotic confinedness, composition of essential oil

Buryatia as a part of Baikalian Siberia is one of the main centers of origin and morphological diversity of wormwood in Eurasia. There are 48 species and subspecies of wormwood within Buryatian flora, one of which is Artemisia gmelinii Web. ex Stechm. For the first time the composition of the essential oils of A. gmelinii growing in the rare community of Siberian apricot ( Armeniaca sibirica (L.) Lam) is presented in this work. Essential oils were obtained from the raw materials collected during the field works on the territory of the Republic of Buryatia (Kyakhtinsky district, surroundings of Tamir village - Southern slopes of the Tamir range) in 2020. The vegetation of the Tamir ranges slope is represented by shrub communities from the relict of Eastern Asia growing since the Miocene-Pliocene time - Armeniaca sibirica . The dominant components of essential oils of A. gmelinii from apricot community are 1,8-cineole, germacrene D, camphor, borneol, caryophyllene. Essential oils of A. gmelinii growing within the Siberian flora of one chemotype with a predominance of mono-terpenoids in the group composition form two subtypes, prevailing: 1) in the East Siberian populations of A. gmelinii with a predominance of sesquiterpenoids in the composition of essential oils; 2) in the West Siberian populations of A. gmelinii with a predominance of monoterpenoids in essential oils.

Using lipidomics to reveal details of lipid accumulation in developing Siberian apricot (Prunus sibirica L.) seed kernels

Background The oil content of Siberian apricot seed kernel (SASK) is generally as high as 50%, and biodiesel fuel properties of SASK oil were conformed to EN 14214 and GB/T 20828-2007 standards. Thus, Prunus sibirica is a novel non-crop feedstock for biodiesel production in China. We have been addressing this issue by studying the regulation of oil accumulation in SASK.Results As part of this research we have carried out a detailed lipidomic analysis in developing SASK. Here, oil contents and fatty acid (FA) compositions were studied in developing SASK from AS-80 and AS-84, at intervals of 1 week from 3 weeks after anthesis (WAA) to 9 weeks. The major differences between the two germplasms are higher contents of C18:1 and C18:2 in AS-80 than in AS-84 at a mature stage. The SASKs of 4, 6 and 8 WAA, respectively representing early, mid and late phases of oil accumulation, were selected as optimal samples for lipidomic analysis. The molecular species in individual lipid classes between AS-80 and AS-84 were similar, and exhibited quite distinct patterns with SASK development. Additionally, the lipidomic data coupled with qRT-PCR analysis suggested that three mechanisms allow the flux of FA through phosphatidylcholine that influenced the molecular composition of eventual TAG.Conclusions The first report on lipidomic analysis during seed development in wood oilseed plants. Our data contribute significantly to understand the underlying mechanisms of lipid accumulation in P. sibirica , and may also present strategies for engineering oil accumulation in oilseed plants.

Using lipidomics to reveal details of lipid accumulation in developing Siberian apricot (Prunus sibirica L.) seed kernels

Background: The oil content of Siberian apricot seed kernel (SASK) is generally as high as 50%, and biodiesel fuel properties of SASK oil were conformed to EN 14214 and GB/T 20828-2007 standards. Thus, Prunus sibirica is a novel non-crop feedstock for biodiesel production in China. We have been addressing this issue by studying the regulation of oil accumulation in SASK. Results: As part of this research we have carried out a detailed lipidomic analysis in developing SASK. Here, oil contents and fatty acid (FA) compositions were studied in developing SASK from AS-80 and AS-84, at intervals of 1 week from 3 weeks after anthesis (WAA) to 9 weeks. The major differences between the two germplasms are higher contents of C18:1 and C18:2 in AS-80 than in AS-84 at a mature stage. The SASKs of 4, 6 and 8 WAA, respectively representing early, mid and late phases of oil accumulation, were selected as optimal samples for lipidomic analysis. The molecular species in individual lipid classes between AS-80 and AS-84 were similar, and exhibited quite distinct patterns with SASK development. Additionally, the lipidomic data coupled with qRT-PCR analysis suggested that three mechanisms allow the flux of FA through phosphatidylcholine that influenced the molecular composition of eventual TAG. Conclusions: The first report on lipidomic analysis during seed development in wood oilseed plants. Our data contribute significantly to understand the underlying mechanisms of lipid accumulation in P. sibirica, and may also present strategies for engineering oil accumulation in oilseed plants.