$¢PhytoKeys

PhytoKeys 251: 67-86 (2025)
DOI: 10.3897/phytokeys.251.133890

Research Article

Morphometric parameters of seeds as a practical method for
identifying rare species of the genus Tulipa L. (Liliaceae) from
East Kazakhstan region

Aidar A. Sumbembayev'®, Olga Lagus™, Alevtina N. Danilova’®, Agnieszka Rewicz”®, Stawomir Nowak?®

1 Altai Botanical Garden, Ermakov St., Ridder 071300, Kazakhstan

2 Department of Geobotany and Plant Ecology, Faculty of Biology and Environmental Protection, University of Lodz, Banacha 12/16, 90-237 Lodz, Poland
3 Department of Plant Taxonomy and Nature Conservation, Faculty of Biology, University of Gdansk, Wita Stwosza 59, 80-308 Gdansk, Poland
Corresponding author: Stawomir Nowak (slawomir.nowak@ug.edu.p!)

OPEN Qaceess

Academic editor: Lorenzo Peruzzi
Received: 6 August 2024
Accepted: 2 December 2024
Published: 16 January 2025

Citation: Sumbembayev AA, Lagus
O, Danilova AN, Rewicz A, Nowak S
(2025) Morphometric parameters

of seeds as a practical method

for identifying rare species of the
genus Tulipa L. (Liliaceae) from East
Kazakhstan region. PhytoKeys 251:
67-86. https://doi.org/10.3897/
phytokeys.251.133890

Copyright: © Aidar A. Sumbembayev et al.
This is an open access article distributed under
terms of the Creative Commons Attribution

License (Attribution 4.0 International - CC BY 4.0).

Abstract

The genus Tulipa includes some of the most important ornamental plants. The aim of
this work was to study the seed morphology of Tulipa species from East Kazakhstan,
including seed coat structure. An analysis focused on five taxa from various natural
environmental conditions. A total of 31 tulip populations were studied to establish mor-
phological variability. Preliminary analyses of the importance of habitat-related eco-
logical factors have been carried out. The results of this study provide new qualitative
characteristics for distinguishing closely related species and are discussed in relation to
their systematic relationships. The structure of the seed coat was studied by Scanning
Electron Microscopy; however, the results did not show significant variability. An identifi-
cation key to determine the species of tulips in East Kazakhstan is proposed.

Key words: 3D ultrastructure, ecological factors, Kazakh Altai, morphometric characteris-
tics, Scanning Electron Microscope (SEM), seed coat, seed morphology, taxonomy, Tulipa

Introduction

The genus Tulipa L. is one of the largest in the family Liliaceae, whose range ex-
tends enormously from Portugal and the northern regions of Africa across the
entire Eurasian continent to the southern islands of Japan (Zonneveld 2009).
All representatives of the genus are known as rare, highly ornamental plants. In
terms of color variation, originality of shape, beauty and flower size, many spe-
cies of wild tulips have a long history in cultivation (Christenhusz et al. 2013;
Wilson 2022). However, wild tulips at the present stage are subject to strong
anthropogenic pressure and without strengthening conservation efforts, the fu-
ture of these beautiful plants in Central Asia may be in serious danger (Wilson
et al. 2021; Dekhkonov et al. 2023). Taking into account limiting factors such
as the narrow ecological amplitude of the species and anthropogenic influ-
ence, many species of tulips, including Tulipa biflora Pall., T. patens C.Agardh,
T. uniflora (L.) Bess. ex Baker, T. heteropetala Ledeb., growing in the territory of
East Kazakhstan region, are included in the Red Book of Kazakhstan (Red Book

67

Aidar A. Sumbembayev et al.: Morphology of seeds of rare Tulipa species in Kazakhstan

of Kazakhstan 2014), and T. altaica Pall. has a protected status in the adjacent
region, the Altai region (Russia) (Alexandrova et al. 2006).

The genus Tulipa has 94 generally known species (POWO 2024), of which 42
species are reported for Kazakhstan (Ivashchenko and Belyalov 2019; Wilson
2022), representing three subgenera: Orythia, Tulipa and Eriostemones (Christen-
husz et al. 2013). The study of wild Kazakh tulips began only at the end of the
18" century. According to Kotukhov (2005), there are five species within the Ka-
zakh Altai, Saur-Manrak and Zaisan Basins (East Kazakhstan region): T. patens
C.Agardh, T. altaica Pall. ex Spreng., T. biflora Pall., T. uniflora (L.) Bess. ex Baker,
T. heteropetala Ledeb. These species are protected in Kazakhstan, adjacent re-
gions (East Kazakhstan region), the Altai region (Russia) (Alexandrova et al. 2006)
and China (Qin et al. 2017), as well as in the IUCN Red Book (IUCN 2024) (Table 1).

Table 1. Rarity status of tulip species from East Kazakhstan.

Species

Status of the species inthe Status of the species in the Red Book of the Altai

Status of the species in | Status of
the Red Book of China __ the species

Red Book of Kazakhstan region (adjacent region) (adjacent region) in the IUCN

Tulipa patens | Ill category. Rare. Species | R(b) — Rare. Rare species found in few localities = LC - least
C.Agardh decreasing in numbers concern

T. altaica Pall. = V(b) — Vulnerable. Vulnerable species, the r LC - least
ex Spreng. northeastern border of its range passes in the concern

region

T. biflora Pall. | category. Rare. = om: LC - least
Threatened concern

T. uniflora (L.) | Ill category. Rare. Species | V(b) — Vulnerable. Vulnerable species. The northern VU - Vulnerable NT — near

Bess. ex Baker | with decreasing range border of its range passes through the region. threatened

T. heteropetala | \l category. Species is a V(a) - Vulnerable. Vulnerable species. Altai- = LC - least
Ledeb. native to Altai, occurring Sayan endemic concern

in small numbers.

The aforementioned threats, including strong anthropopressure, both on hab-
itats and uncontrolled plant harvesting, make easy identification of species at
different stages of development extremely important for conservation purposes.

There are numerous studies on the biology of the genus Tulipa in terms of tax-
onomy (Mordak 1990; Christenhusz et al. 2013; Wilson 2022), ontogenesis (Ab-
dusalam and Tan 2014), genetics (Zonneveld 2009; Kiani et al. 2012; Pourkhaloee
et al. 2018; Asgari et al. 2020; Haerinasab et al. 2021; Hajdari et al. 2021; Li et al.
2021), population geography (Tojibaev and Beshko 2015; Trias-Blasi et al. 2017;
Abduraimov et al. 2018; Pechenitsyn et al. 2020; Dekhkonov et al. 2023) and karyol-
ogy (Masoud et al. 2002). However, studies on the structure and variability of seeds
in the genus are still lacking. There are a limited number of works on the seed
productivity of tulips (Zhang et al. 2020; Lidzhieva et al. 2021; Zhang et al. 2023).

The study of the morphology of seeds of closely related species is highly import-
ant in terms of biodiversity. The morphology of seeds, along with the morphology
of flowers, inflorescences and fruits, is among the dominant generative character-
istics of taxonomy (Dekhkonov et al. 2022). The knowledge gained helps to find the
place of species in genera and families, as well as in general plant classification.
The external structure of seeds, surface structure features, and weight characteris-
tics can serve as important additional features in the taxonomy of the genus.

Understanding both the macro- and microstructure of seeds is highly import-
ant for plant taxonomy and phylogenetic inference, as highlighted by various

PhytoKeys 251: 67-86 (2025), DOI: 10.3897/phytokeys.251.133890 63

Aidar A. Sumbembayev et al.: Morphology of seeds of rare Tulipa species in Kazakhstan

studies (Duckett and Soni 1972a, 1972b; Behnke and Barthlott 1983; Mourad et
al. 2010). The application of biometric and seed sculpture analysis has proven
to be a valuable tool for tasks such as classification, ecological studies, and
identification of species. Seed characteristics play crucial roles in linking phe-
notypic features to generic relationships and in circumscribing subtribes within
various genera (Heywood and Dakshini 1971; Pfosser et al. 2003; Rewicz et
al. 2017). Seed shape, in particular, has emerged as a vital aspect in certain
taxonomic studies, standing alongside seed sculpture as one of the most con-
sistent species-specific traits (Pfosser et al. 2003).

The morphology of generative organs, particularly seeds, could be a key
feature in determining the species identity of a plant (Lipinska et al. 2022;
Sumbembayev et al. 2023). Moreover, data on morphology for many species of
the Tulipa genus are incomplete (Zonneveld 2015; Xing et al. 2017; Dekhkonov
et al. 2022), and for Kazakhstan, they are fragmentary (Zonneveld and De Groot
2012; Epictetov and Belyalov 2013; lvashchenko and Belyalov 2019).

The purpose of this study was to assess the morphological parameters for
seeds of the Tulipa species from the East Kazakhstan region (based on biomet-
ric traits and scanning electron microscopy), as well as to analyze their biomet-
ric according to the ecological and habitat factors in the study region, including
systematic relationships in the genus. Finally, to propose a dichotomous key to
species determination based on the analyzed features.

Materials and methods
Biometric analyses

The focus of this study was the seeds of five species (T. altaica, T. biflora, T.
heteropetala, T. patens, T. uniflora) of tulips from 31 populations collected from
natural populations in the East Kazakhstan region in various ecological and
geographical habitats (Fig. 1). The species nomenclature is based on POWO
(2024). The systematics of the genus and sectional division are accepted
according to the works of Van Raamsdonk et al. (1996), Christenhusz et al.
(2013), and Wilson (2022).

The survey territory was the entire East Kazakhstan region. It has an area of
more than 97 thousand square kilometers, which borders the Altai region (Rus-
sia) in the north and China in the west (Fig. 1). The region has a wide range of
natural conditions, from deserts to alpine meadows.

Seed material was collected in sites from East Kazakhstan region. Collec-
tions were made from 2010-2020 by Professor Yu.A. Kotukhov; the seeds were
stored dry in paper bags at 18-20 °C. Fully formed seed samples were selected
for the study. All thirty-one studied populations are characterized in details by
geographical coordinates, description of the locality and habitat, and the Ellen-
berg indicators values in the Suppl. material 1.

Twenty seeds from each population of Tulipa were analyzed. The following
four seed traits were quantified: a) length, b) width, c) thickness, and d) weight
of 1000 seeds. Moreover, the qualitative characteristics of the seeds, such as
color, shape, testa surface, state of the micropyle (micropyle), chalazal end
(chalaza), seed hilum (hilum), structure and surface of the seed suture (raphe),
endosperm (endospermium) and embryo (embryo), were described (Fig. 2).

PhytoKeys 251: 67-86 (2025), DOI: 10.3897/phytokeys.251.133890 69

Aidar A. Sumbembayev et al.: Morphology of seeds of rare Tulipa species in Kazakhstan

) Y
| | Ridder @)
| s 2
| e Nal Russia
} h hy * *
P & | Oskemen 5
- 50.0
EY
| o
49.5
<9
49.0
48.5
48.0

82.0 82,5 83.0 83.5 84.0 84,5 85.0 85.5 86.0
Figure 1. Collection sites of studied species of the genus Tulipa in the East Kazakhstan region. The color of the dot re-
flects the species: yellow - T. uniflora, orange - T. patens, pink - T. biflora, green - T. altaica, turquoise - T. heteropetala, and
the numbers reflect the populations studied.

Figure 2. Schematic seed structure of the genus Tulipa: a main view b side view c top view. Seed features are marked
by numbers (with Latin terms in brackets): 1 — micropyle (micropyle), 2 — chalazal end (chalaza), 3 — seed hilum (hilum),
4 — seed suture (raphe), 5 - endosperm (endospermium), and 6 — embryo (embryo). Measurements taken in this study:
| — width, Il — length, and III — thickness.

PhytoKeys 251: 67-86 (2025), DOI: 10.3897/phytokeys.251.133890 0

Aidar A. Sumbembayev et al.: Morphology of seeds of rare Tulipa species in Kazakhstan

SEM analyses

The seeds were sputter-coated with a 4 nm layer of gold before being subjected
to SEM observation. Seed ornamentation characteristics were studied by Scan-
ning Electron Microscopy (SEM) (Phenom Pro X) at the Department of Inverte-
brate Zoology and Hydrobiology, University of Lodz (Poland) (Suppl. material 4:
figs S1-S5). Seed surface ultrastructure 3D models were generated via 3D rough-
ness reconstruction via a phenom electron microscope (Fig. 4). The digital imag-
es obtained via SEM were trimmed and arranged in plates via Corel Draw 2018.

The shapes of individual seed coat cells, the anticlinal wall, and the surface
structure of the periclinal wall are classified into Barthlott (1984).

Statistical analyses

Seed morphology was studied via a MAGUS D9T stereomicroscope. The shape
and surface of the seeds were described using the method proposed by Martin
(1946). Schemes of seed structure based on average metric characteristics were
designed in the AutoCAD graphic program. The diagrams show the appearance
of the studied seeds. The maximum seed sizes are indicated by a dotted line.

The Shapiro—Wilk and Kolmogorov—Smirnov tests were conducted to check
for a normal distribution of the data. One-way analysis of variance (ANOVA)
with statistics F was used to determine whether the investigated morphological
seed traits differed among the Tulipa populations (Zar 1984). Cluster analysis
UPGMA tree was constructed using R (R Core Team 2021) with packages: pop-
pr (Kamvar et al. 2014), ggplot2 (Wickham 2016), dplyr (Wickham et al. 2023),
dendextend (Galili 2015), RColorBrewer (Neuwirth 2014), vegan (Oksanen et al.
2017), GUniFrac (Chen et al. 2023), labdsv (Roberts 2023).

Principal component analysis (PCA), correlation analysis, ANOVA and spe-
cies dendrograms were constructed in R (with packages; dplyr, dendextend,
RColorBrewer, ggplot2, vegan, GUniFrac, labdsv). The ecological conditions of
the habitats of the studied populations were assessed according to the Ellen-
berg ecological scales (Tichy et al. 2023). Seed color was established accord-
ing to the MacAdam (1974) color scale.

Results

In the study area, East Kazakhstan, the largest populations of tulips were
found in the Zaisan depression, as well as the Narym and Kurchum ridges.
The occurrence is dominated by rocky sites and diverse vegetation steppes,
as well as scrub (Suppl. material 1). Examination of the seed morphology
of five species of tulips collected under different ecological and geographic
conditions showed similarity within species but variation in shape and size
among them (Fig. 3).

The study of the external morphometry of tulip seeds, which is based on lin-
ear dimensions (length, width and thickness), as well as the weight of the seeds,
clearly revealed a high degree of variation in all the parameters (Suppl. material 2).

A description of the external and internal structure of T. patens, T. altaica,
T. biflora, T. uniflora, and T. heteropetala made it possible to identify morpho-
logical features characterizing the external and internal characteristics of tulip

PhytoKeys 251: 67-86 (2025), DOI: 10.3897/phytokeys.251.133890 7

Aidar A. Sumbembayev et al.: Morphology of seeds of rare Tulipa species in Kazakhstan

Figure 3. Seeds of the genus Tulipa: A T. heteropetala B T. altaica C T. biflora D T. patens E T. uniflora F comparison of
studied seeds of the genus Tulipa of the Kazakh Altai.

seeds for practical use in species determination and with reference to the sys-
tematic relationships (Suppl. material 3).

The color of the seeds of the studied species of the genus Tulipa ranges
from brown to reddish-brown. The shape of the seeds is flat, vaguely triangu-
lar or wedge-shaped and curved wedge shaped. The test surface varies from
rough to wrinkled. In all the studied species, the micropyle is overgrown, the
seed hilum is depressed and longitudinally slit-like, the raphe from thickened
and smooth to thickened, the endosperm is developed, and the shape of the
embryo is either straight or curved toward the raphe or strongly curved.

T. altaica produced the largest and heaviest seeds. The width of the seeds of
T. uniflora was the smallest, while the weight of the 1000 seeds differed slightly
from those in T. altaica. Compared with T. altaica, the seeds of T. heteropeta-
la should be classified as small. T; patens has the lightest and flattest seeds.
The average length and weight of 1000 seeds of T. biflora and T. uniflora differ
slightly from each other; significant differences in these species were found in
the width and thickness of the seeds.

Analysis of seed micromorphology via SEM and 3D models (Fig. 4) did
not reveal significant differences in the structure of the seed coat. The anti-
clinal walls in all the species are straight, and the periclinal walls are mostly
smooth (e.g., Suppl. material 4: figs S1A-D, S2C, D, S3B). Analyses of the
shape of individual seed coat cells revealed that, in most species, they are
elongated and rectangular (e.g. Suppl. material 4: figs S1B, S2C) or elongat-
ed and rounded (e.g. Suppl. material 4: figs S4B, S5A). More or less irregular
or rectangular cells were observed on the edges of the seeds (e.g., Suppl.
material 4: figs S1A, S3F, S5C).

PhytoKeys 251: 67-86 (2025), DOI: 10.3897/phytokeys.251.133890 79

Lidar

oe

— ns ;
SS Cp a th

D, E T. biflora F T. patens.

ise)
—
is)
~
®
o
Nw
®
~
®o
<
K
<
a)
xe)
®o
®o
wn
xe)
oO
N
=
©
=
©
oO
om
_—
eae
[o)
n
1D)
1S)
©
Ee
uu
=)
wn
oO
pl el
_~
ee
oO
®o
=
=}
_—
(S)
=)
ra
~
n
©
pes
a,
3
oD)
ps
~
ee
oO
ae)
co)
xo)
fe)
=
a
c
=
wn
Cc
oO
E
be
oO
®o
=
pi ex
EE
a
o
=
=)
5
LL

Aidar A. Sumbembayev et al.: Morphology of seeds of rare Tulipa species in Kazakhstan

PhytoKeys 251: 67-86 (2025), DOI: 10.3897/phytokeys.251.133890

B T. uniflora C T. altaica

Aidar A. Sumbembayev et al.: Morphology of seeds of rare Tulipa species in Kazakhstan

Principal component analysis (PCA) of individuals of the genus Tulipa (Fig. 5)
revealed the quality of the samples performed and demonstrated the differenc-
es and similarities among all the samples of the studied species. Significant
isolation of T. altaica samples from other species along coordinate 1 was re-
vealed. T. uniflora and T. patens are qualitatively separated from other species
along coordinate 2. All the species are qualitatively separated from each other,
with almost no overlaps. Species of the subgenus Eriostemones T. biflora and
T. patens are significantly separated along coordinate 2 and are not intersected
by ellipses. Species of the section Orithyia: T. uniflora and T. heteropetala are
located quite close together, but there are practically no noticeable intersec-
tions, and these species are qualitatively separated along coordinate 2, which
indicates the independence of the species under consideration.

co
o~
a
=
0
N
=
a)

1
NO

Figure 5. Principal component analysis (PCA) of individual seeds measured of the genus Tulipa in East Kazakhstan.
Explanation: W - width of seed, L — length of seed, T — thickness of seed, X1000S — weight of 1000 seeds. Each dot
represents one individual seed measured and the color of the dot reflects the species: yellow - T. altaica, black - T. biflora,
green - T. heteropetala, blue - T. patens, red - T. uniflora.

Principal component analysis (PCA) of species differences (Fig. 6) re-
vealed similarities and differences between populations within each tulip
species. A clear isolation of T. altaica populations from populations of other
species was revealed. The populations of T. heteropetala and T. uniflora are
spatially separate. Remarkably, the narrowness of the population distribu-
tion of these species indicates that the choice of the number of populations
for analysis is sufficient.

Cluster analysis of the ranking of populations of species of the genus Tulipa
according to external morphometric and weight characteristics, presented in a
dendrogram (Suppl. material 5), graphically arranged the studied populations
according to similarity and difference. All T. altaica populations were included
in cluster 1. High similarity of seed material was established between popula-
tions of the species T. heteropetala and T. patens, forming cluster 2. Important-
ly, the populations of T. heteropetala and T. uniflora, which belong to the same
section, Orithyia, are located strictly in different clusters—in the second and
third clusters, respectively.

PhytoKeys 251: 67-86 (2025), DOI: 10.3897/phytokeys.251.133890 74

Aidar A. Sumbembayev et al.: Morphology of seeds of rare Tulipa species in Kazakhstan

<
=
bd
=
of
—
™N
=
QO

X1000S _

0 1
Dim 1(63.9%)
Figure 6. Principal component analysis (PCA) for populations of species of the genus
Tulipa from East Kazakhstan. Explanation: W — width of seed, L — length of seed, T -
thickness of seed, X1000S — weight of 1000 seeds. Each dot represents one population
studied and the color of the dot reflects the species: yellow - T. altaica, black - T. biflora,
green - T. heteropetala, blue - T. patens, red - T. uniflora.

The cluster dendrogram (Fig. 7), which was constructed on the basis of inter-
specific similarity and differences, revealed the morphological consistency of
the seed material in T- patens, T. biflora and T. heteropetala, which formed single
cluster 3. Further, species belonging to the same section Orithyia, T. uniflora and
T. heteropetala, are located in different clusters.

T. altaica 4)

(Subgenus Tulipa
Section Kolpakowskianae)

I. uniflora 2)
(Subgenus Orithyia
Section Orithyia)

T. biflora

(Subgenus Eriostemones
Section Biflores)

I. patens
(Subgenus Eriostemones
Section Sylvestres)

T. heteropetala

(Subgenus Orithyia

Section Orithyia)
Figure 7. Dendrogram of the interspecific similarity of species of the genus Tulipa from
East Kazakhstan.

PhytoKeys 251: 67-86 (2025), DOI: 10.3897/phytokeys.251.133890 45

Aidar A. Sumbembayev et al.: Morphology of seeds of rare Tulipa species in Kazakhstan

Correlation analysis of the dependence of the main linear and weight character-
istics of seeds on environmental conditions revealed strong, stable direct and in-
verse correlations in all species of the genus Tulipa (Suppl. material 6). Strong di-
rect correlations were established for T. patens and T. uniflora between the weight
of 1000 seeds and soil moisture (M) and nutrients (N). A weak inverse correlation
was also observed between seed length and soil salinity in T. patens and T. altaica.

Analysis of variance (ANOVA) (Table 2) revealed that some environmental fac-
tors can significantly influence the morphometric characteristics of seeds of the
genus Tulipa. The following significant influences of environmental factors were
established: temperature (T) on the morphometric characteristics of T. heteropeta-
la, T. patens and T. uniflora; light (L) on the morphometric characteristics of T. pat-
ens and T. uniflora; and nutrients (N) for T. patens, T. heteropetala, and T. uniflora.

ANOVA (Table 3) for the all studied Tulipa species from East Kazakhstan
combined, revealed a significant effect of almost all the environmental factors
on seed length. In addition, the size and weight of the seeds are influenced the
most by light (L) and nutrients (N).

Table 2. Results of analysis of variance (ANOVA) by species.

T. altaica

weight of 1000 seeds
length
width

T. biflora

weight of 1000 seeds
length
width

T. heteropetala

weight of 1000 seeds
length
width

T. patens

weight of 1000 seeds
length
width

T. uniflora

weight of 1000 seeds

length
width

Factor/trait

thickness

thickness

thickness

thickness

thickness

L T M R N S) T:M T:R

kk

Significance codes: 0 ‘***’ 0.001 ‘**’ 0.01 ** 0.05 '' 0.1" 1.

Table 3. Results of analysis of variance (ANOVA) by genus.

Factor/trait Species
length aE
width

thickness

kkk
kkk
weight of ie
1000 seeds

L|T) M/}R_/#N |S. species:L | species:T | L:T

kk

kkk

kkk

kkk

species:M T:M_ species:R T:R_ | M:R_ species:N R:N

kkk | kkk kkk kkk kk kkk * kkk kkk kkk

kkk kkk kk kkk kkk

kkk kkk kkk kkk * kkk kkk

kkk kkk kkk * kkk kkk kkk kkk kkk kkk

Significance codes: 0 ‘***’ 0.001 ‘**’ 0.01 ‘* 0.05 ‘’ 0.1" 1.

PhytoKeys 251: 67-86 (2025), DOI: 10.3897/phytokeys.251.133890

76

Aidar A. Sumbembayev et al.: Morphology of seeds of rare Tulipa species in Kazakhstan

Figure 8. Schemes of the standard external structure of species of the genus Tulipa from the East Kazakhstan region,
compiled on the basis of average linear sizes: A T. patens B T. altaica C T. biflora D T. uniflora E T. heteropetala. a - main
view; b — side view; c — top view; maximum dimensions are indicated by a dotted line.

Summarizing morphometric analysis for populations of the Tulipa species,
diagrams of the standard external structure of tulip seeds from the East Ka-
zakhstan region were constructed (Fig. 8).

Discussion

The study of rare and endangered plant species is one of the main tasks in
solving the problem of preserving the biological diversity of Kazakhstan. Since
monitoring nature is largely based on morphology, providing more data in help-
ing their accurate identification should be the most accessible and reliable as
possible. The study of similar species of tulips is actively carried out throughout
the range of these species. Previously, Kiani et al. (2012) and Asgari et al. (2020)
carried out molecular analyses of T. biflora and other tulips in Iran. Li et al. (2021)
performed phylogenetic analysis of T. patens and T. altaica in China. Masoud et
al. (2002) performed a karyological study of T. biflora and other tulip species in
Iran. Xing et al. (2017) studied the morphology of T. a/taica and other wild tulip
species in Xinjiang (Western China). Tojibaev and Beshko (2015) studied the
distribution and status of populations of T. biflora and other tulips in Uzbekistan.
As a result of our study, the morphobiological characteristics of seeds for five
species of the genus Tulipa in the East Kazakhstan region were determined. Thus,
our results complement the fundamental data on the external and internal struc-
ture of species such as T. patens, T. altaica, T. biflora, T. uniflora, and T. heterop-
etala and have a great potential to be used for species identification in a region.

PhytoKeys 251: 67-86 (2025), DOI: 10.3897/phytokeys.251.133890 oa

Aidar A. Sumbembayev et al.: Morphology of seeds of rare Tulipa species in Kazakhstan

The sizes of the seeds of the studied species differ slightly, which indi-
cates moderate heterogeneity of the seeds and low adaptive potential of the
studied plants. This fact indicates a narrow range of Tulipa patens, T. altaica,
T. biflora, T. uniflora, and T. heteropetala in the regional flora. A comparison
of the weight indicators of species of the genus Tulipa also revealed slight
variability in this trait across the region. Principal component analysis (PCA)
for populations and for individuals of species of the genus Tulipa reliably
and qualitatively separates all species at both the species and section levels.
Populations of T. altaica are significantly different from those of other tulips
in East Kazakhstan. However, a limiting element of our study is the lack of
embryo measurements, and it is worth conducting such studies for the genus
Tulipa in the future. Recent studies indicate (Carta et al. 2024) that this may
be one of the key traits in the analysis of seed functionality and the evolution-
ary trends in angiosperms.

Cluster analysis and a dendrogram for interspecific similarity of species
graphically demonstrated the clear distinctiveness of T. altaica and T. uniflora
and the lack of such for T. heteropetala and T. patens.

Correlation analysis of the dependence of seed size and weight on growing
conditions indicate the potential dependence on soil moisture and richness, as
well as soil salinity. In addition, no constant relationship has been established
between seed size and important factors for flowering plants, such as light
and temperature. ANOVA revealed that environmental factors had a greater
influence on seed length, and, the richness of the soil affect the seed size.
However, the results obtained should be treated as preliminary research due
to the limitation of the samples collected. The species studied show a much
wider range of occurrence than within the East Kazakhstan region, so a more
comprehensive study requires collecting a representative sample from the
entire distribution range and including climatic data. Especially since studies
show (Carta et al. 2022) that climate is a strong predictor of germination
response, moreover, this trait has a strong association with phylogeny.

Importantly, qualitative differences in the external and internal character-
istics of the seeds of two species, T. uniflora and T. heteropetala, were ob-
served during the study. The characteristics of the seeds of these two species
are qualitative features for distinguishing them as independent species. On
the basis of our research, we consider that distinctiveness of T. heteropetala
could be justified.

The study of seed coat micromorphology did not reveal significant differ-
ences between the examined Tulipa species. These differences are minimal
or insignificant, making it difficult to distinguish species on the basis of seeds.
In the context of the studied species, the lack of differentiation suggests that
seed micromorphology is not a useful tool for their identification (Heywood and
Dakshini 1971). There are several potential reasons for this phenomenon. First,
the sculpture of the seed coat may be too conservative, meaning that it has
not undergone significant evolutionary changes among different species. Such
conservatism may result from a stable environment that does not exert selec-
tive pressure, leading to differentiation of the seed ultrastructure. Additionally,
variability of seed structure could be very limited due to the strong conserva-
tism of the features related to their optimal adaptation to fulfill their primary
functions (Stace 1993).

PhytoKeys 251: 67-86 (2025), DOI: 10.3897/phytokeys.251.133890 79

Aidar A. Sumbembayev et al.: Morphology of seeds of rare Tulipa species in Kazakhstan

The phylogeny within the genus Tulipa is rather well understood, and many
relationships are resolved. However, many species concepts still need to be
clarified. Within the studied species, for example, there are different definitions
of T. altaica or the complexity of T. biflora (Wilson 2022; Sutula et al. 2024). It
seems that phylogenetic relationships do not have much significance in the
case of seed structure, so many similar traits can develop under environmental
pressures, which may suggest the statistical significance of some of the fac-
tors studied (Tables 2, 3; Suppl. material 6). Closely related and classified within
one section, species such as T. uniflora and T. heteropetala do not show much
similarity (Wilson 2022; Sutula et al. 2024). On the other hand, T. uniflora was
the only one to be collected from a distinct area, which may confirm that the
impact of habitat factors is important in shaping seed traits in the genus Tulipa.

Conclusion

The genus Tulipa in East Kazakhstan is represented by five rare and endangered
species: T. patens, T. altaica, T. biflora, T. uniflora and T. heteropetala. The seeds
of all species of tulips from East Kazakhstan differ qualitatively from each oth-
er not only in size and weight but also morphologically in characteristics such
as micropyle, chalazal end, seed hilum, raphe, endosperm and embryo.

As a result of this study, the possibility of using the morphology of tulip
seeds as a systematic feature was confirmed. The difference in seed materi-
al was clearly shown in two closely related species from the Orithyia section:
T. uniflora and T. heteropetala. Currently, the morphology of seeds is the most
reliable feature for distinguishing these closely related species. The study of
the comparative morphological characteristics of tulip seeds has made it pos-
sible to identify a group of characteristics that can be used to clarify the taxo-
nomic affiliation of species. The established morphological characteristics of
the seeds made it possible to develop an identification key for species of the
genus Tulipa in the East Kazakhstan region. However, it is impossible to identify
a single seed trait that differentiates all species. Therefore, the determination
key uses only the key features and the best discriminating species. To obtain
the best possible determination, we suggest using a set of various data, includ-
ing descriptive ones as in this research.

On the other hand, the ultrastructures of seeds do not show much variation,
most likely because the high conservatism of seed structure and phylogenet-
ic relationships are not reflected in the seed structure. However, owing to the
demonstration of overall seed variability, it is worthwhile to undertake research
on a larger sample of the genus Tulipa to fully understand the reasons for this
variability. This is especially true for a genus of great ornamental importance
that is highly under threat.

Key to the Tulipa species in the East Kazakhstan region

1 Seeds are noticeably thickened in the basal part and curved in shape;
the tips of the seeds and the chalaza are turned toward the raphe;
the testa is longitudinally furrowed; the chalazal end is transversely
GROOVE Se vascnsescetnssn tinscperiest suicides usace tists T. uniflora (L.) Bess. ex Baker.

r: Seeds with other CharacteristiCS.............ccccccccescecccesssseceeeeesseeeceesssseeeeees 2

PhytoKeys 251: 67-86 (2025), DOI: 10.3897/phytokeys.251.133890 79

Aidar A. Sumbembayev et al.: Morphology of seeds of rare Tulipa species in Kazakhstan

2 The seeds are quite large, up to 7 mm in length and around 6 mm in
width, with a noticeably elongated tip; the surface of the seeds is finely
veined; the chalazal end is smooth................. T. altaica Pall. ex Spreng.

= The seeds are small, without an elongated tip; chalazal end is rough
CRUE ReLE=W VIDIO cosa: cor be OA tase ta Ri Aonsctat th Yezease tA Reo Racccaae) 3

3 The seed surface is finely tuberous; the seed embryo is strongly curved
TE WAGES SAD C.F te sa cence tara tear tet odemeinaeeahas ecu cere! T. biflora Pall.

= The seed surface is rough and wrinkled; the embryo is rectilinear in

4 The seeds are brown; the seed hilum is protruding and longitudinally
slit-shaped; and the raphe has a smooth Surface ..................c0cccceeeeeee
Sona eee Ne AA pet orth corres Dor rere ge ENS oe ccna he T. patens C.Agardh
“ Seeds are orange-brown to reddish-brown in color; the seed hilum is
concave and ellipsoidal in shape; raphe is grooved ..............:ccessceceeseeeees
Se rac theron dh actos azateis easbu cava acta pac ah aye raademamerhe ss qeaeves T. heteropetala Ledeb.

Acknowledgements

We are grateful to Professor Yuri Kotukhov for providing seed material, assist-
ing in preparing the article and providing valuable instructions. We would like
to thank prof. Angelino Carta and an anonymous reviewer for all their valuable
comments on an earlier version of the manuscript.

Additional information

Conflict of interest

The authors have declared that no competing interests exist.

Ethical statement

No ethical statement was reported.

Funding

The article was prepared under the scientific and technical program BR18574125 “Study
of the current state of the species diversity of vascular plants in Kazakhstan using mod-
ern methods of botany, molecular genetics and bioinformatics” (2023-2024), Ministry
of Science and Higher Education, Republic of Kazakhstan.

Author contributions

Conceptualization: AAS, OL, AND. Data curation: AAS. Formal analysis: AAS, AR. Fund-
ing acquisition: AAS. Investigation: AAS, OL. Methodology: AR, AAS. Project adminis-
tration: AAS. Supervision: SN, AND. Validation: AND, SN, AR, OL. Visualization: SN, AR.
Writing - original draft: OL, AND, AAS, AR, SN.

Author ORCIDs

Aidar A. Sumbembayev © https://orcid.org/0000-0003-0682-9162
Olga Lagus © https://orcid.org/0000-0001-7178-2888

Alevtina N. Danilova © https://orcid.org/0000-0002-1096-9339
Agnieszka Rewicz ® https://orcid.org/0000-0002-8228-6406
Stawomir Nowak © https://orcid.org/0000-0002-0496-1023

PhytoKeys 251: 67-86 (2025), DOI: 10.3897/phytokeys.251.133890 30

Aidar A. Sumbembayev et al.: Morphology of seeds of rare Tulipa species in Kazakhstan

Data availability

All of the data that support the findings of this study are available in the main text or
Supplementary Information.

References

Abduraimov OS, Shomurodov HF, Daniyarov SA (2018) The current state of cenopopu-
lation of Tulipa micheliana Hoog in Uzbekistan. American Journal of Plant Sciences
9(8): 1725-1739. https://doi.org/10.4236/ajps.2018.98125

Abdusalam A, Tan DY (2014) Contribution of temporal floral closure to reproductive
success of the spring-flowering Tulipa iliensis. Journal of Systematics and Evolution
52(2): 186-194. https://doi.org/10.1111/jse.12036

Alexandrova OV, Vaganov AV, Vereshchagina IV, German DA, Associates (2006) Red
Book of the Altai Territory. Rare and endangered plant species. Barnaul, 1-262.

Asgari D, Babaei A, Naghavi MR, Kiani M (2020) Biodiversity status of Tulipa (Liliaceae)
in Iran inferred from molecular characterization. Horticulture, Environment and
Biotechnology 61(3): 559-567. https://doi.org/10.1007/s13580-019-00158-0

Barthlott W (1984) Microstructural features of seed surface. In: Heywood VH, Moore DM
(Eds) Current Concepts in Plant Taxonomy. Academic Press, London, 52-105.

Behnke HD, Barthlott W (1983) New evidence from the ultrastructural and micromor-
phological fields in angiosperm classification. Nordic Journal of Botany 3(1): 43-66.
https://doi.org/10.1111/j.1756-1051.1983.tb01444.x

Carta A, Fernandez-Pascual E, Gioria M, Muller JV, Riviere S, Rosbakh S, Saatkamp A,
Vanderlook F, Mattana E (2022) Climate shapes the seed germination niche of tem-
perate flowering plants: A meta-analysis of European seed conservation data. Annals
of Botany 129(7): 775-786. https://doi.org/10.1093/aob/mcac037

Carta A, Vandelook F, Ramirez-Barahona S, Chen SC, Dickie J, Steinbrecher T, Thanos
CA, Moles AT, Leubner-Metzger G, Mattana E (2024) The seed morphospace, a new
contribution towards the multidimensional study of angiosperm sexual reproductive
biology. Annals of Botany 134(5): 701-710. https://doi.org/10.1093/aob/mcae099

Chen J, Zhang X, Yang L, Zhang L (2023) GUniFrac: Generalized UniFrac Distances, Distance-
Based Multivariate Methods and Feature-Based Univariate Methods for Microbiome
Data Analysis. R package version 1.8. https://CRAN.R-project.org/package=GUniFrac

Christenhusz MJ, Govaerts R, David JC, Hall T, Borland K, Roberts PS, Tuomisto A, Buerki
S, Chase M, Fay MF (2013) Tiptoe through the tulips—cultural history, molecular phy-
logenetics and classification of Tulipa (Liliaceae). Botanical Journal of the Linnean
Society 172(3): 280-328. https://doi.org/10.1111/boj.12061

Dekhkonov D, Tojibaev K, Yusupov Z, Makhmudjanov D, Asatulloev T (2022) Morphology
of tulips (Tulipa, Liliaceae) in its primary centre of diversity. Plant Diversity of Central
Asia 1(1): 52-70. https://doi.org/10.54981/PCDA/vol1_iss1/a1

Dekhkonov D, Asatulloev T, Akbarov F, Tojiboeva U, Lorenzo P Tojibaev KS (2023)
Conservation strategy and diversity of Tulipa (Liliaceae) in Uzbekistan. Plant Diversity
of Central Asia 4: 1-42. https://doi.org/10.54981/PDCA/vol2_iss2/a2

Duckett JG, Soni SL (1972a) A scanning electron microscopic study of leaf surfaces
of some species of Scapania Dum. (Hepaticae). Journal of Bryology 7(1): 75-79.
https://doi.org/10.1179/jbr.1972.7.1.75

Duckett JG, Soni SL (1972b) Scanning electron microscope studies on the leaves of
Hepaticae. 1. Ptilidiaceae, Lepidoziaceae, Calypogeiaceae, Jungermanniaceae, and
Marsupellaceae. The Bryologist 75(4): 536-549. https://doi.org/10.2307/3241208

PhytoKeys 251: 67-86 (2025), DOI: 10.3897/phytokeys.251.133890 31

Aidar A. Sumbembayev et al.: Morphology of seeds of rare Tulipa species in Kazakhstan

Epictetov VG, Belyalov OV (2013) A new species of the genus Tulipa L. (Liliaceae) from Ka-
zakhstan. Turezaninowia 16(3): 5-7. https://doi.org/10.14258/turczaninowia. 16.3.1

Galili T (2015) dendextend: An R package for visualizing, adjusting and comparing trees
of hierarchical clustering. Bioinformatic 31(22): 3718-3720. https://doi.org/10.1093/
bioinformatics/btv428

Haerinasab M, Molavi Z, Jalilian N, Eslami-Farouji A (2021) Genetic diversity and popu-
lation structure of some Iranian Tulipa species within the subgenus Eriostemones us-
ing CDDP method. Iranian Journal of Science and Technology, Transaction A, Science
45(4): 1273-1285. https://doi.org/10.1007/s40995-021-01144-x

Hajdari A, Pulaj B, Schmiderer C, Mala X, Wilson B, Lluga-Rizani K, Mustafa B (2021) A
phylogenetic analysis of the wild Tulipa species (Liliaceae) of Kosovo based on plas-
tid and nuclear DNA sequence. Advanced Genetics 2(3): e202100016. https://doi.
org/10.1002/ggn2.202100016

Heywood VH, Dakshini KMM (1971) Fruit structure in the Umbelliferae-Caucalideae. The
biology and chemistry of the Umbelliferae. Botanical Journal of the Linnean Society
64(Suppl. 1): 215-232.

IUCN (2024) The IUCN Red List of Threatened Species. Version 2024-1. https://www.
iucnredlist.org [Accessed: 15.07.2024]

lvashchenko AA, Belyalov OV (2019) Kazakhstan is the birthplace of tulips. Almaty, 1-368.

Kamvar ZN, Tabima JF, Grunwald NJ (2014) Poppr: An R package for genetic analysis of
populations with clonal, partially clonal, and/or sexual reproduction. PeerJ 2: e281.
https://doi.org/10.7717/peerj.281

Kiani M, Memariani F, Zarghami H (2012) Molecular analysis of species of Tulipa L. from
lran based on ISSR markers. Plant Systematics and Evolution 298(8): 1515-1522.
https://doi.org/10.1007/s00606-01 2-0654-0

Kotukhov YA (2005) List of vascular plants of the Kazakhstan Altai. Botanical Studies of
Siberia and Kazakhstan 11: 11-83.

Li J, Price M, Su DM, Zhang Z, Yu Y, Xie DF, Zhou SD, He XJ, Gao XF (2021) Phylogeny
and comparative analysis for the plastid genomes of five Tulipa (Liliaceae). BioMed
Research International 2021(1): 6648429. https://doi.org/10.1155/2021/6648429

Lidzhieva N, Antonova A, Ubushaeva S, Ochirova A, Ovadykova J (2021) Seed produc-
tivity of coenopopulations of Tulipa gesneriana L. (Liliaceae) on the Ergeninskaya
Upland (Within the Boundaries of the Republic of Kalmykia). KnE Life Sciences 6(3):
870-876. https://doi.org/10.18502/klIs.v0i0.9024

Lipinska MM, OledrzynskaN, Portilla A,Luszczek D, Sumbembayev AA, Szlachetko DL (2022)
Maxillaria anacatalinaportillae (Orchidaceae, Maxillariinae), a new remarkable species
from Ecuador. PhytoKeys 190: 15-33. https://doi.org/10.3897/phytokeys.190.77918

MacAdam DL (1974) Uniform color scales. Journal of the Optical Society of America
64(12): 1691-1702. https://doi.org/10.1364/JOSA.64.001691

Martin AC (1946) The comparative internal morphology of seeds. American Midland
Naturalist 36(3): 513-660. https://doi.org/10.2307/2421457

Masoud §, Shirin ZF, Shadi K, Bahram Z (2002) Karyotypic study in some Iranian species
and populations of Tulipa L. (Liliaceae). Caryologia 55(1): 81-89. https://doi.org/10.
1080/00087114.2002.10589261

Mordak EV (1990) What are Tulipa schrenkii Regel and T. heteropetala Ledeb. (Liliaceae)?
News of Taxonomy of Higher Plants 27: 27-32.

Mourad MM, Hamed KA, Rabie SS (2010) Implication of the numerical analysis of seed
characters on the taxonomic treatment of some taxa of Liliaceae. Egyptian Journal
of Experimental Biology (Botany) 6: 147-159.

PhytoKeys 251: 67-86 (2025), DOI: 10.3897/phytokeys.251.133890 99

Aidar A. Sumbembayev et al.: Morphology of seeds of rare Tulipa species in Kazakhstan

Neuwirth E (2014) RColorBrewer: ColorBrewer Palettes. R Package Version 1.1-3.
https://CRAN.R-project.org/package=RColorBrewer

Oksanen FJ, Simpson GL, Blanchet FG, Kindt R, Legendre P Minchin PR, O'Hara RB, Soly-
mos P Henry M, Stevens H, Szoecs E, Wagner H, Barbour M, Bedward M, Bolker B,
Borcard D, Carvalho G, Chirico M, De Caceres M, Durand S, Evangelista HBA, FitzJohn
R, Friendly M, Furneaux B, Hannigan G, Hill MO, Lahti L, McGlinn D, Ouellette M-H,
Cunha ER, Smith T, Stier A, Ter Braak CUF, Weedon J (2017) Vegan: Community Ecol-
ogy Package. R package Version 2.4-3. https://CRAN.R-project.org/package=vegan

Pechenitsyn VP, Turgunov MD, Beshko NY, Abdullaev DA (2020) Rare species of Tulipa
(Liliaceae) from Tashkent Botanical Garden. Acta Biologica Sibirica 6: 385-397.
https://doi.org/10.3897/abs.6.e55940

Pfosser M, Wetschnig W, Ungar S, Prenner G (2003) Phylogenetic relationships among
genera of Massonieae (Hyacinthaceae) inferred from plastid DNA and seed morphol-
ogy. Journal of Plant Research 116(2): 115-132. https://doi.org/10.1007/s10265-
003-0076-8

Pourkhaloee A, Khosh-Khui M, Arens P, Salehi H, Razi H, Niazi A, Afsharifar A, van Tuyl
J (2018) Molecular analysis of genetic diversity, population structure, and phylo-
geny of wild and cultivated tulips (Tulipa L.) by genic microsatellites. Horticulture,
Environment and Biotechnology 59(6): 875-888. https://doi.org/10.1007/s13580-
018-0055-6

POWO (2024) Plants of the World Online. Facilitated by the Royal Botanic Gardens, Kew.
https://powo.science.kew.org [Accessed: 15.07.2024]

Qin H, Yang Y, Dong §S, He Q, Jia Y, Zhao L, Yu S, Liu H, Liu B, Yan Y, Xiang J, Xia N, Peng
H, Li Z, Zhang Z, He X, Yin L, Lin Y, Liu Q, Hou Y, Liu Y, Liu Q, Cao W, Li J, Chen S, Jin X,
Gao T, Chen W, Ma H, Geng Y, Jin X, Chang C, Jiang H, Cai L, Zang C, Wu J, Ye J, Lai Y,
Liu B, Lin Q, Xue N (2017) Threatened species list of China’s higher plants. Shengwu
Duoyangxing 25(7): 696-744. https://doi.org/10.17520/biods.2017144

R Core Team (2021) R: A language and environment for statistical computing. R Founda-
tion for Statistical Computing, Vienna. https://www.R-project.org/

Red Book of Kazakhstan (2014) 2", revised and expanded Edition. Volume 2.: Plants.
Astana, 1-452.

Rewicz A, Bomanowska A, Magda J, Rewicz T (2017) Morphological variability of Con-
solida regalis seeds of south-eastern and central Europe. Systematics and Biodiversi-
ty 15(1): 25-34. https://doi.org/10.1080/14772000.2016.1216017

Roberts DW (2023) labdsv: Ordination and Multivariate Analysis for Ecology. R package
version 2.1-0. https://CRAN.R-project.org/package=labdsv

Stace CA (1993) Plant Taxonomy and Biosystematics. Cambridge University Press,
1-264.

Sumbembayev AA, Lagus OA, Nowak S (2023) Seed morphometry of Rheum L. (Polygona-
ceae) species from Kazakhstan and its implications in taxonomy and species iden-
tification. Biodiversitas (Surakarta) 24(9): 4677-4692. https://doi.org/10.13057/
biodiv/d240908

Sutula M, Kakanay A, Tussipkan D, Dzhumanov S, Manabayeva S (2024) Phylogenetic
analysis of rare and endangered Tulipa species (Liliaceae) of Kazakhstan based on
universal barcoding markers. Biology (Basel) 13(6): 365. https://doi.org/10.3390/bi-
ology13060365

Tichy L, Axmanova I, Dengler J, Guarino R, Jansen F, Midolo G, Nobis MP, Van Meerbeek
K, AGié S, Attorre F, Bergmeier E, Biurrun I, Bonari G, Bruelheide H, Campos JA, Carni
A, Chiarucci A, Cuk M, CuSterevska R, Didukh Y, Dité D, Dité Z, Dziuba T, Fanelli G,

PhytoKeys 251: 67-86 (2025), DOI: 10.3897/phytokeys.251.133890 93

Aidar A. Sumbembayev et al.: Morphology of seeds of rare Tulipa species in Kazakhstan

Fernandez-Pascual E, Garbolino E, Gavilan RG, Gégout J-C, Graf U, Giller B, Hajek M,
Hennekens SM, Jandt U, JaSkova A, Jiménez-Alfaro B, Julve P Kambach S, Karger DN,
Karrer G, Kavgaci A, Knollova |, Kuzemko A, Kuzmic F, Landucci F, Lengyel A, Lenoir
J, Marceno C, Moeslund JE, Novak P, Pérez-Haase A, Peterka T, Pielech R, Pignatti A,
RaSomavicius V, Risina S, Saatkamp A, Silc U, Skvore Z, Theurillat J-P, Wohlgemuth T,
Chytry M (2023) Ellenberg-type indicator values for European vascular plant species.
Journal of Vegetation Science 34(1): e13168. https://doi.org/10.1111/jvs.13168

Tojibaev K, Beshko N (2015) Reassessment of diversity and analysis of distribution in
Tulipa (Liliaceae) in Uzbekistan. Nordic Journal of Botany 33(3): 324-334. https://
doi.org/10.1111/njb.00616

Trias-Blasi A, Giicel S, Ozden O (2017) Current distribution and conservation status re-
assessment of the Cyprus Tulip (Tulipa cypria: Liliaceae), new data from Northern
Cyprus. Plant Biosystems-An International Journal Dealing with all Aspects of Plant
Biology 151(3): 394-402. https://doi.org/10.1080/11263504.2016.1174177

Van Raamsdonk LWD, Eikelboom W, De Vries T, Straathof TP (1996) The systematics
of the genus Tulipa L. VII International Symposium on Flowerbulbs 430: 821-828.
https://doi.org/10.17660/ActaHortic.1997.430.131

Wickham H (2016) ggplot2: Elegant Graphics for Data Analysis. Springer-Verlag New
York. https://ggplot2.tidyverse.org

Wickham H, Francois R, Henry L, Miller K, Vaughan D (2023) dplyr: A Grammar of Data
Manipulation. R package version 1.1.4 [https://dplyr.tidyverse.org]. https://github.
com/tidyverse/dplyr

Wilson B (2022) Tulipa: the taxonomy and evolutionary history of the genus and its impact
on conservation priorities in Central Asia. PhD thesis, University of Cambridge, UK.

Wilson B, Dolotbakov A, Burgess BJ, Clubbe C, Lazkov G, Shalpykov K, Ganybaeva M,
Sultangaziev O, Brockington SF (2021) Central Asian wild tulip conservation requires
a regional approach, especially in the face of climate change. Biodiversity and Con-
servation 30(6): 1705-1730. https://doi.org/10.1007/s10531-021-02165-z

Xing G, Qu L, Zhang Y, Xue L, Su J, Lei J (2017) Collection and evaluation of wild tulip
(Tulipa spp.) resources in China. Genetic Resources and Crop Evolution 64(4): 641-
652. https://doi.org/10.1007/s10722-01 7-0488-2

Zar JH (1984) Simple linear regression. Biostatistical Analysis 4: 324-359.

Zhang W, Qu LW, Zhao J, Xue L, Dai HP Xing GM, Lei JJ (2020) Practical methods for
breaking seed dormancy in a wild ornamental tulip species Tulipa thianschanica Re-
gel. Agronomy (Basel) 10(11): 1765. https://doi.org/10.3390/agronomy10111765

Zhang W, Zhao J, Xue L, Dai H, Lei J (2023) Seed morphology and germination of native
Tulipa species. Agriculture 13(2): 466. https://doi.org/10.3390/agriculture13020466

Zonneveld BJ (2009) The systematic value of nuclear genome size for “all” species of
Tulipa L. (Liliaceae). Plant Systematics and Evolution 281(1—-4): 217-245. https://
doi.org/10.1007/s00606-009-0203-7

Zonneveld BJ (2015) Tulipa jacquesii (Liliaceae), a new species from Western Kyrgyz-
stan. Phytotaxa 218(2): 184-188. https://doi.org/10.11646/phytotaxa.218.2.9

Zonneveld BJM, De Groot JJ (2012) Tulipa kolbintsevii Zonn., a new species from East-
ern Kazakhstan. Plant Systematics and Evolution 298(7): 1293-1296. https://doi.
org/10.1007/s00606-012-0635-3

PhytoKeys 251: 67-86 (2025), DOI: 10.3897/phytokeys.251.133890 34

Aidar A. Sumbembayev et al.: Morphology of seeds of rare Tulipa species in Kazakhstan

Supplementary material 1

Description of the population locations of Tulipa species in East Kazakhstan
region

Authors: Aidar A. Sumbembayev, Olga Lagus, Alevtina N. Danilova, Agnieszka Rewicz,
Stawomir Nowak

Data type: pdf

Copyright notice: This dataset is made available under the Open Database License
(http://opendatacommons.org/licenses/odbl/1.0/). The Open Database License
(ODbL) is a license agreement intended to allow users to freely share, modify, and
use this Dataset while maintaining this same freedom for others, provided that the
original source and author(s) are credited.

Link: https://doi.org/10.3897/phytokeys.251.133890.suppl1

Supplementary material 2
Morphometric characteristics of Tulipa seeds from different growing areas

Authors: Aidar A. Sumbembayev, Olga Lagus, Alevtina N. Danilova, Agnieszka Rewicz,
Stawomir Nowak

Data type: pdf

Copyright notice: This dataset is made available under the Open Database License
(http://opendatacommons.org/licenses/odbl/1.0/). The Open Database License
(ODbL) is a license agreement intended to allow users to freely share, modify, and
use this Dataset while maintaining this same freedom for others, provided that the
original source and author(s) are credited.

Link: https://doi.org/10.3897/phytokeys.251.133890.suppl2

Supplementary material 3

Indicators of morphological characteristics of seeds of species of the
genus Tulipa in East Kazakhstan region

Authors: Aidar A. Sumbembayev, Olga Lagus, Alevtina N. Danilova, Agnieszka Rewicz,
Stawomir Nowak

Data type: pdf

Copyright notice: This dataset is made available under the Open Database License
(http://opendatacommons.org/licenses/odbl/1.0/). The Open Database License
(ODbL) is a license agreement intended to allow users to freely share, modify, and
use this Dataset while maintaining this same freedom for others, provided that the
original source and author(s) are credited.

Link: https://doi.org/10.3897/phytokeys.251.133890.suppl3

PhytoKeys 251: 67-86 (2025), DOI: 10.3897/phytokeys.251.133890 95

Aidar A. Sumbembayev et al.: Morphology of seeds of rare Tulipa species in Kazakhstan

Supplementary material 4

Seed coat micromorphology of Tulipa species, seen under Scaning Electron
Microscope

Authors: Aidar A. Sumbembayev, Olga Lagus, Alevtina N. Danilova, Agnieszka Rewicz,
Stawomir Nowak

Data type: pdf

Copyright notice: This dataset is made available under the Open Database License
(http://opendatacommons.org/licenses/odbl/1.0/). The Open Database License
(ODbL) is a license agreement intended to allow users to freely share, modify, and
use this Dataset while maintaining this same freedom for others, provided that the
original source and author(s) are credited.

Link: https://doi.org/10.3897/phytokeys.251.133890.suppl4

Supplementary material 5

Cluster analysis of the similarity of populations of species of the genus
Tulipa from East Kazakhstan according to external metric and weight
indicators

Authors: Aidar A. Sumbembayev, Olga Lagus, Alevtina N. Danilova, Agnieszka Rewicz,
Stawomir Nowak

Data type: pdf

Copyright notice: This dataset is made available under the Open Database License
(http://opendatacommons.org/licenses/odbl/1.0/). The Open Database License
(ODbL) is a license agreement intended to allow users to freely share, modify, and
use this Dataset while maintaining this same freedom for others, provided that the
original source and author(s) are credited.

Link: https://doi.org/10.3897/phytokeys.251.133890.suppI5

Supplementary material 6

Correlation between morphometric characteristics of seeds of species of
the genus Tulipa and environmental conditions

Authors: Aidar A. Sumbembayev, Olga Lagus, Alevtina N. Danilova, Agnieszka Rewicz,
Stawomir Nowak

Data type: pdf

Explanation note: A Tulipa patens B T. altaica C T. biflora D T. uniflora E T. heteropetala.

Copyright notice: This dataset is made available under the Open Database License
(http://opendatacommons.org/licenses/odbl/1.0/). The Open Database License
(ODbL) is a license agreement intended to allow users to freely share, modify, and
use this Dataset while maintaining this same freedom for others, provided that the
original source and author(s) are credited.

Link: https://doi.org/10.3897/phytokeys.251.133890.suppl6

PhytoKeys 251: 67-86 (2025), DOI: 10.3897/phytokeys.251.133890 86