Microsoft Word - 11585 NSB Wang 2023.06.28.docx


Received: 01 Jun 2023. Received in revised form: 26 Jun 2023. Accepted: 27 Jun 2023. Published online: 28 Jun 2023. 

From Volume 13, Issue 1, 2021, Notulae Scientia Biologicae journal uses article numbers in place of the traditional method of 
continuous pagination through the volume. The journal will continue to appear quarterly, as before, with four annual numbers. 
 

 
 
 

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Society of TransylvaniaSociety of TransylvaniaSociety of TransylvaniaSociety of Transylvania 

Wang P et al. (2023) 

Notulae Scientia BiologicaeNotulae Scientia BiologicaeNotulae Scientia BiologicaeNotulae Scientia Biologicae    
Volume 15, Issue 2, Article number 11585 

DOI:10.15835/nsb15211585 
    Research ArticleResearch ArticleResearch ArticleResearch Article.... 

NSBNSBNSBNSB    
Notulae Scientia Notulae Scientia Notulae Scientia Notulae Scientia 

BiologicaeBiologicaeBiologicaeBiologicae 

 
 

IIIIn vitron vitron vitron vitro    regeneration ofregeneration ofregeneration ofregeneration of    HaloxylonHaloxylonHaloxylonHaloxylon    ammodendronammodendronammodendronammodendron    
 

Ping WANG, Lingjuan MAN, Li MA, Jiaxin QI, Yanping REN,  
Zhengpei YAO, Bo WANG, Cong CHENG, Hua ZHANG* 

 
Xinjiang Agricultural University, College of Life Sciences, Urumqi, Xinjiang, China; 1827278246@qq.com; 990559779@qq.com; 

125667729@qq.com; 874531321@qq.com; renyanping923@163.com; yaozp@xjau.edu.cn; wangbo@xjau.edu.cn; 

2017216030@njau.edu.cn; hazelzhang@163.com (*corresponding author) 

 
AbstractAbstractAbstractAbstract    
    
Haloxylon ammodendron (C.A.Mey) Bunge is one of the important species of arid desert vegetation in 

China, and it is also an ideal material for studying plant stress resistance, which plays an extremely important 
role in protecting desert ecosystems and preventing land desertification. However, there are relatively few 
studies on the regeneration of the fusiform, and the genetic transformation system has not been successfully 
reported, which restricts the in-depth study of the molecular mechanism of shuttle propagation and stress 
resistance. In the present study, the seeds, hypocotyls, cotyledons, cotyledon nodes, terminal buds and fixed 
buds were used as explants, and a set of tissue culture and plant regeneration system was established by inducing 
adventitious buds, adventitious bud rooting and transplanting. The results showed that amongst different H. 

ammodendron explants, i.e., seeds, hypocotyls, cotyledons and cotyledon nodes, the last induced budding effect 

was better. The optimal medium for inducing clandine buds by cotyledon segment differentiation is 0.5 mg·L-

1 NAA+0.5 mg·L-1 6-BA induced budding rate was high, reaching 61.90%, rooting medium was 1/2 MS+1 

mg·L-1 NAA +1 mg·L-1 IBA + 1 mg·L-1 IAA with a rooting rate of 50%. The results of this study will provide 
a theoretical basis for the genetic transformation of H. ammodendron. 

    
Keywords:Keywords:Keywords:Keywords: adventitious buds; root induction; organogenesis; ex vivo regeneration; H. ammodendron 

 
 
IntroductionIntroductionIntroductionIntroduction    
 
Haloxylon ammodendron is a small perennial tree of the genus Haloxylon in the family Amaranthaceae, 

widely distributed in desert areas of Asia and Africa, and is a major building block of desert vegetation. In 
China, H. ammodendron is mainly distributed in Xinjiang, Inner Mongolia, Qinghai, Gansu and Ningxia 

provinces and regions; H. ammodendron is a small perennial tree, sometimes shrub-like, which is unique to 

desert areas drought tolerance (when the soil moisture content is 1.3~2.6%, it can still grow normally), high 
temperature resistance, salinity resistance (salt resistance critical range can reach 4% ~ 6%), wind erosion 
resistant plants (Kung et al., 1979). It is a typical C4 species of high drought tolerance and salt tolerance 

(Casati et al., 1999), having the morphological and physiological characteristics of a super-arid plant. To 

adapt to the environment of extreme soil water scarcity and intense transpiration at high temperatures, H. 

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ammodendron degenerates into scale-like, juicy green shoots (‘assimilated shoots’) with high salt content, 

which can be used as preferred fodder for livestock and is a woody fodder in desert arid areas (Kazuo et al., 

2000; Xu et al., 2007; Wu et al., 2019). 

H. ammodendron forests play an important role in protecting the security of the oasis by fixing a large 

amount of drifting sand around the oasis and have a high ecological value in combating desertification (Su et 

al., 2007; Maina et al., 2015). The natural desert vegetation (known as "desert forest") formed by H. 

ammodendron as the dominant species provides a suitable breeding environment for nearly 200 species of desert 

plants, and also provides a habitat and breeding place for many desert animals and insects, which is an important 
place for biodiversity conservation in desert plain areas, and has important ecological and economic value in 
mitigating desertification, maintaining regional ecological balance and protecting the ecological environment. 

Under natural conditions, H. ammodendron is reproducing extensively by seeds, which have a short 

germination retention period and are prone to interspecific variation and intergenerational degeneration. The 
heterogeneity of its germplasm and limited germination shelf life, limit the natural renewal and development 
of H. ammodendron. The high degree of lignification and thin bast of assimilated branches of H. ammodendron 

is one of the reasons why it is difficult to form adventitious roots. Using relatively young and tender branches 
for cuttings, the spike rot is also serious, resulting in cuttings rooting cannot continue, and using histogenic 
seedling technology can overcome these shortcomings. The use of in vitro culture technology allows not only 
to obtain new plantings and varieties, but also to obtain the metabolic substances required by humans. Still, the 
plant tissue culture technology has a high reproduction factor and can provide a large number of seedlings in a 
short period of time. Tissue culture of woody plants has always had problems such as low reproduction 
coefficient, difficulty in rooting and serious pollution. However, with the development of time, a variety of 
regeneration systems for fruit trees and forest trees have been successfully established, for example, Zhang et al. 

(2014) used apple leaves as explants to obtain regenerated plants. Bertsouklis et al. (2023) studied in vitro 

propagation of Juniperus oxycedrus adult native plants, examining the effects of seasonal explant collection 

(spring, summer, winter), different culture media, and cytokinin types. There are also citrus (Jardak et al., 

2020), fir (Hu et al., 2017) and pine (Kim et al., 2014) that have successfully established regeneration systems. 

Some economically important species have been widely used in plantation production, such as poplar (Chan et 

al., 2016) and eucalyptus (Fernando et al., 2016). Yu-Qing et al. (2018) used leaves of Zenia insignis Chun as 

explants to obtain regenerated fertile plants through guaired tissue induction, adventitious shoot induction, 
and rooting. In view of this, the present study was conducted to investigate the shoot induction and 
adventitious shoot rooting of H. ammodendron weeds, hypocotyls, cotyledons, cotyledon nodes, terminal buds 

and fixed buds as experimental materials, with a view to providing a theoretical basis for genetic transformation 
of H. ammodendron. 

 
 

Materials and MethodsMaterials and MethodsMaterials and MethodsMaterials and Methods    
 
Seed treatment and acquisition of sterile seedlings 

Picked uniform and full seeds of H. ammodendron weeds (harvested from Gurbantunggut Desert in 

northern Jimsar County, Changji Prefecture, Xinjiang. -20 °C for storage), add 75% (v/v) ethanol, shake for 3 
min, discard the liquid; rinse with sterile water 3 times, shake for 3 min; finally soak the seeds with sodium 
hypochlorite for 10 min, rinse with sterile water 6 times; soak in sterile water overnight, cultured on MS solid 
medium the next day to germinate, and obtain sterile seedlings of H. ammodendron after 35 d (Figure 1). 

 



Wang P et al. (2023). Not Sci Biol 15(2):11585 

 

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Figure 1.Figure 1.Figure 1.Figure 1.    H. ammodendron sterile seedlings (Note: A: seed B: hypocotyl C: cotyledon D: cotyledon nodes 

E: fixed bud F: terminal bud) 

 
Induction of indeterminate buds 

 When the sterile seedlings grew to 3-5 cm, the hypocotyl, cotyledons, cotyledon nodes, staple buds and 
terminal buds of about 0.5-1 cm in size were rapidly cultured into the germination induction medium, three 
bottles of each combination of different hormone concentrations, and seven explants were inoculated in each 
bottle. Germination was observed and recorded 10 days after inoculation. Germination percentage = (number 
of explants forming shoots/number of inoculated explants) × 100%. (See Results and Analysis section for 
details of hormone combinations) 

Three hormones IBA (Indole-3-butyric acid), NAA (1-naphthal acetic acid), and IAA (Indole acetic 
acid) were added to the basic medium of 1/2 MS, and four hormone concentration gradients of 1, 2, 3, and 4 
mg L-1 were orthogonally designed for the induction of adventitious roots in 16 treatments. After the 
adventitious shoots induced by the H. ammodendron nodes grew about 0.5~1 cm in size, they were put into 

the induction rooting culture flasks; three replicate controls were made for each treatment, and about 7 
explants were placed in each culture flask. After 35 d of incubation, the growth status was observed and the 
rooting rate was counted. Rooting percentage (%) = number of rooted plants/number of inoculated explants 
× 100%. The data were processed with Microsoft Excel 2010 software. (See Results and analysis section for 
details of hormone fractions).  

 

Refining seedlings for transplanting 

The regenerated seedlings with well-developed root systems and more robust growth were opened in the 
artificial climate chamber, cling film was applied, small holes were poked in the cling film, and the seedlings 
were refined for about one week, then the regenerated seedlings were removed from the culture bottles, the 
medium attached to the root surface was rinsed with sterile water, transplanted into sterilized vermiculite: 
charcoal: sand = 1:1:1, and placed in the culture room for cultivation. 



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Results Results Results Results     
 
Effect of different hormone concentration ratios on the induction of adventitious shoots  

From the results of the experiment, it can be seen that H. ammodendron seeds, cotyledon nodes, fixed 

buds and terminal buds can be induced to germinate, but hypocotyl and cotyledons did not germinate (Table 
1). During the experimental observation, it was found that seeds and cotyledons emerged preferentially within 
14 d, while fixed and terminal buds emerged one after another after 14 d. Since the material of fixed and 
terminal buds was difficult to obtain, although the seeds could also induce buds, it could be seen from the 
pictures that the quality of the buds was not as good as that of the indeterminate buds induced by the cotyledon 
nodes, and for the consideration of subsequent rooting, the most suitable explants for the induction of buds 
were determined to be the cotyledon nodes (Figure 2). 

The cotyledonary nodes were induced in treatment 11 with a higher rate of 61.90% at MS + 0.5 mgL-1 

NAA + 0.5 mgL-1 6-BA. The induced shoots had vigorouw growth and dark green color. In treatment 3, 
cotyledonary nodes did not induce buds when no phytohormones were added, thus showing that 
phytohormones play a very important role in cotyledonary node induction of buds. The germination rate of 

cotyledon nodes in treatment 8 and 13, MS+1 mg·L-1 IBA+1 mg·L-1 KT was 14.5%, MS+1 mg·L-1 NAA+1 

mg·L-1 6-BA was 23.81%, which indicated that the combination of NAA and 6-BA and IBA and KT hormones 
was at a concentration of 1 mgL-1, it is not suitable as a medium for cotyledon nodes, inducing adventitious 
buds. The budding rate of cotyledonary node in treatment 5 and 15 was the same, second only to treatment 11, 
and the budding rate reached 57.14%. In the combination with high germination rate, 6-BA was found to be 
involved, indicating that 6-BA played a role in the process of inducing adventitious budding in the H. 

ammodendron cotyledonary node. Germination of cotyledon nodes started within 14 d. Adventitious shoots 

were vigorous, had normal leaf color, usually appeared in compact clusters, and it was difficult to quantify the 
number of regenerated shoots, with a few vitrification seedlings, but no deformed shoots. 

 

 
FigureFigureFigureFigure    2222.... Induction of germination from six exosomes of H. ammodendron (35d)  

(Note: A: seed B: hypocotyl C: cotyledon D: cotyledon nodes E: fixed bud F: terminal bud) 

 
 



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TableTableTableTable    1111....    Effect of adding different hormone concentration ratios on germination induction of six explants 
(% germination induction rate) 

Treatment 
code 

Media type A seed 
B 

hypocotyl 
C 

cotyledon 

D 
cotyledonary 

nodes 

E fixed 
bud 

F 
terminal 

bud 

1 
MS+0.5 mg·L-1 6-BA+1 mg·L-1 

KT 
76.01ab 0 0 33.33bcde 47.62ab 28.57ab 

2 
MS+1 mg·L-1 6-BA+0.5 mg·L-1 

KT 
61.9abc 0 0 42.86abcde 33.33ab 23.81ab 

3 MS 42.86bc 0 0 0f 0b 0b 

4 
MS+0.5 mg·L-1 IBA+1 mg·L-1 

6-BA+1 mg·L-1 KT 
47.62bc 0 0 47.62abcd 23.81ab 33.33ab 

5 
MS + 0.5 mg·L-1 IBA + 0.5 

mg·L-1 6-BA 
61.91abc 0 0 57.14ab 38.1ab 23.81ab 

6 
MS + 0.5 mg·L-1 IBA + 0.5 

mg·L-1 KT 
47.62bc 0 0 52.38abc 0b 19.05ab 

7 
MS+1 mg·L-1 IBA+1 mg·L-1 6-

BA 
71.43abc 0 0 28.57cde 4.76ab 23.81ab 

8 
MS+1 mg·L-1 IBA+1 mg·L-1 

KT 
47.62bc 0 0 14.5ef 0b 0b 

9 
MS+1 mg·L-1 IBA+0.5 mg·L-1 

6-BA+0.5 mg·L-1 KT 
38.1c 0 0 47.62abcd 33.33ab 14.29ab 

10 
MS+0.5 mg·L-1 NAA+1 mg·L-

1 6-BA+1 mg·L-1 KT 
71.43abc 0 0 42.86abcde 33.33ab 52.38a 

11 
MS+0.5 mg·L-1 NAA+0.5 

mg·L-1 6-BA 
71.43abc 0 0 61.9a 52.38a 33.33ab 

12 
MS + 0.5 mg·L-1 NAA + 0.5 

mg·L-1 KT 
61.9abc 0 0 52.38abc 23.81ab 9.52b 

13 
MS+1 mg·L-1 NAA+1 mg·L-1 

6-BA 
66.67abc 0 0 23.81de 0b 0b 

14 
MS+1 mg·L-1 NAA+1 mg·L-1 

KT 
66.67abc 0 0 33.34bcde 47.62ab 23.81ab 

15 
MS+1 mg·L-1 NAA+0.5 mg·L-

1 6-BA+0.5 mg·L-1 KT 
85.71a 0 0 57.14ab 28.57ab 33.33ab 

Note: different letters indicate significant differences at P ≤ 0.05 

 
Effects of different concentrations of IBA, NAA and IAA on the rooting of regenerated plants 

The results of 1/2 MS as the basal medium with different concentrations of IAA, IBA, and NAA were 
used to induce rooting of adventitious shoots in the culture, and the results are shown in Table 2 below. From 

the test results, it can be seen that the highest rooting rate of adventitious shoots in 1/2 MS + 1 mg·L-1 IBA + 

1 mg·L-1 NAA + 1 mg·L-1 IAA medium was 50%, and the average root length was 6.96 mm. In the course of 
the experiment, It was found that the overall rooting was better when 1/2 MS was used as the basal medium 
than when MS was used as the basal medium, so 1/2 MS was used as the basal medium for subsequent 
adventitious shoot induction rooting. Although the rooting rate was higher when 1/2 MS was used as the basal 
medium, the effective number of roots was lower, and during the rooting process, most of the adventitious 
shoots in the medium would gradually disappear, leaving only a large number of healed and adventitious roots 
produced. After the main roots had lignified and a certain number of fibrous roots had grown, the caps of the 
histoponic bottles were left open for a small period of time; after 1~2 d, the caps were left open for another 
period of time to allow the regenerated seedlings to gradually adapt to the natural environment. After one week 
of refinement, the root medium of the regenerated seedlings was rinsed with sterile water and transferred into 
sterilized vermiculite: charcoal: sand = 1:1:1. To maintain a certain temperature and humidity, the nursery 
pots for transplanting regenerated seedlings were covered in multiple layers using cling film. 



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Based on the above results and the observation during the experiment, it is concluded that the seeds, 
cotyledons, fixed buds and top buds can induce budding, and the cotyledons have the best bud-inducing effect, 

and the most suitable medium for cotyledons to induce budding is MS+0.5 mg·L-1 NAA+0.5 mg·L-1 6-BA, 
the germination rate was 61.9%, and the budding was successively after 14 days. The optimal medium for 

inducing adventitious bud rooting is 1/2 MS+1 mg·L-1 NAA +1 mg·L-1 IBA + 1 mg·L-1 IAA, with a rooting 
rate of 50%, took root after 14 days, and the H. ammodendron regeneration system of organogenesis was 

successfully established. 
 

 
FigureFigureFigureFigure    3333....    Flow chart of organogenesis regeneration system of H. ammodendron  
(Note: A: H. ammodendron weed; B: sterile seedling; C: Cotyledon nodes; D~G: cotyledon node induced shoot; 
H~K: adventitious shoot induced rooting; L: H. ammodendron regenerated seedling; M~O: transplant) 

 
TableTableTableTable    2.2.2.2. Effects of adding different concentrations of hormones on the rooting of regenerated plants with 
1/2 MS as the base medium 

Treatment 
code 

IBA  
(mg·L )-1 

NAA 
(mg·L )-1 

IAA 
(mg·L )-1 

Rooting rate 
(%) 

Average root 
length(mm) 

Growth 

1 2 2 4 8.5b 0.75b 
After the formation of healing wounds, the 
buds fade away, with roots but no buds 

2 2 1 2 0b 0b 
After the formation of healing wounds, the 
buds fade away, with roots but no buds 

3 4 1 4 0b 0b 
After the healing wound is formed, the 

buds fade away. 

4 3 2 1 18.5ab 3.5ab 
After the healing wound is formed, the 

buds fade away. 

5 3 1 3 8.5ab 1.9ab 
More roots, shorter, more healing, fewer 

shoots, slower growth 

6 1 3 4 14.5ab 4.17ab 
More roots, slender, fewer shoots, more 

healing tissue 

7 1 1 1 50a 6.96a 
Many roots, good growth condition, more 
healing tissue, forming a complete plant 

8 1 4 2 36.5ab 1.52b 
Many roots, slender, with roots and shoots, 

slow-growing 

9 3 4 4 33.5ab 1.3b 
After the formation of healing wounds, the 
buds fade away, with roots but no buds 

10 4 2 3 47a 1.36b 
Few slender roots, no buds, many healing 

wounds, slow growth 

11 4 2 2 36ab 1.87ab 
After the formation of healing wounds, the 
buds fade away, with roots but no buds 

12 4 4 3 0b 1.23b 
After the formation of healing wounds, the 
buds fade away, with roots but no buds 

13 2 4 1 40.5ab 2.39ab 
After the formation of healing wounds, the 
buds fade away, with roots but no buds 



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14 3 3 2 12.5ab 1.56b 
After the formation of healing wounds, the 
buds fade away, with roots but no buds 

15 4 3 1 8.5ab 1.97ab 
After the healing wound is formed, the 

buds fade away. 

16 2 3 3 24.5ab 1.9ab 
Buds disappeared, only healing wounds 

remain, roots few, slender 

 
 
DiscussionDiscussionDiscussionDiscussion    
 
The use of plant tissue culture techniques to obtain regenerated plants directly or indirectly through the 

somatic embryo pathway or organogenesis pathway is the basis for biotechnological breeding, protoplast 
culture, somatic cell hybridization and gene transformation research. In this study, the induction of 
adventitious buds was carried out using H. ammodendron seeds, hypocotyls, cotyledons, cotyledon nodes, fixed 

buds and terminal buds as explants, and it was found that H. ammodendron seeds, cotyledon nodes, fixed buds 

and terminal buds could be induced to produce buds, but hypocotyls and cotyledons did not produce buds. 
The cotyledonary nodes showed fast and high germination rate when germination was induced. Due to the 
long time for the formation of definitive and terminal buds in H. ammodendron sterile seedlings, the source of 

material was limited and time-consuming; the cotyledon nodes induced better quality of germination, and the 
cotyledon nodes were finally identified as the best explants for germination induction. Yasmin et al. (2003) 

showed that the types and proportions of different exogenous plant hormones have a significant effect on the 
regeneration of the same plant. 6-BA favours cell division and affects organ differentiation, and in agreement 
with Chen and Gao reported (Dabauza et al. 1977), a mixed fraction of 6-BA and growth hormone was found 

to increase the rate of germination induction in Plumbago auriculata. Higher 6-BA concentrations strongly 

inhibited shoot elongation, resulting in little or no production of large shoots. This finding is consistent with 
the cotyledon explants of kale type oilseed rape (Xiaolan et al. 2001). This may be because the plant has reached 

a specific balance between internal and external hormones and the hormone receptors are saturated (Miedema, 
1984; Pasqualetto et al., 1986; Leshem et al., 1988; Liu et al., 2008) found that high levels of cytokinins can 

cause vitrification in in vitro cultures of phytoplankton with high water content, respectively. However, there 
was no significant vitrification of adventitious shoots in the present study. The specific cause of this problem 
deserves further investigation. 

In addition, it was found in the pre-test pre-experiment that the H. ammodendron regeneration seedlings 

could be rooted when MS and 1/2 MS were used as the base medium, but it was found that the growth of 
explants on 1/2 MS medium was better than MS during the test observation, so in this experiment, we chose 
1/2 MS as the base medium for rooting, and the rooting rate could reach when IBA, IAA & NAA were added 
to 1/2 MS 50%. During the rooting phase, IBA, IAA, and NAA are the three most used hormones. The effects 
of IBA on rooting have been shown to be more effective than other plant growth regulators (Amiri and 
Elahinia, 2011). In addition, the addition of NAA had some promotion effect on the growth of adventitious 
roots. This may be due to the appropriate concentration of growth hormone acting on the cells, which 
facilitates the binding to ATPase on the plasma membrane. This acidifies the cell wall environment and some 
unstable hydrogen bonds are easily broken, allowing the molecular structures of cell wall polysaccharides to 
interweave. The cell wall tends to relax, making it easy for the cells forming adventitious roots to break through 
(Li et al., 2009). Therefore, it is necessary to investigate the optimal concentration for rooting. In addition, 

many studies have shown that IAA can promote root formation and growth, such as banana and bergamot 
(Miilion et al., 2015; Jose et al., 2015). Although the root rate of this graduate student is high, most adventitious 

shoots will disappear in the later culture, and only calluses and adventitious roots will appear, which is guessed 
to be related to the concentration of plant hormones, and subsequent experiments also need to adjust the 
concentration of plant hormones to induce rooting. Browning, vitrification, and contamination are relatively 
common and poorly controlled phenomena in in vitro plant culture. Vitrification is a physiological lesion in 



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which the regenerated shoots are translucent and have an abnormal morphological appearance. The majority 
of vitrification seedlings are adventitious shoots from stem tips or stem cut cultures, and usually the recovery 
percentage of vitrification seedlings is very low, and vitrification seedlings still form in succession cultures. In 
this experiment, the occurrence of vitrification seedlings was less frequent at the induction stage of shoot 
emergence, and it was observed that the occurrence of vitrification seedlings was reduced accordingly by 
decanting the residual water in the culture flasks. 

In summary, this study establishes a system for H. ammodendron regeneration by organogenesis. The 

method will provide a basis for the application of H. ammodendron ex vivo regeneration and genetic 

transformation. 
 
    
ConclusionsConclusionsConclusionsConclusions    
 
It plays an extremely important role in protecting desert ecosystems and preventing desertification. Ex 

vivo reproduction is an effective method for species conservation and restoration. In this study, six explants of 
the H. ammodendron were used to establish an ex vivo regeneration system of the shuttle by inducing 

adventitious buds, adventitious bud rooting and transplanting. The optimal medium for inducing clandine 

buds in cotyledon nodes differentiation is 0.5 mg·L-1 NAA+0.5 mg·L-1 6-BA induced budding rate was high, 

reaching 61.90%, rooting medium was 1/2 MS+1 mg·L-1 NAA +1 mg·L-1 IBA + 1 mg·L-1 IAA with a rooting 
rate of 50%. This study will lay a solid technical foundation for in-depth study of the molecular mechanism of 
drought resistance and cultivation of excellent germplasm.    
 
 

Authors’ ContributionsAuthors’ ContributionsAuthors’ ContributionsAuthors’ Contributions 
 
Conceptualization: Hua Zhang and Bo Wang; Data curation: Ping Wang, Lingjuan Man and Li Ma; 

Formal analysis: Ping Wang, Lingjuan Man and Li Ma; Investigation: Ping Wang, Lingjuan Man and Li Ma, 
Jiaxin Qi; Methodology: Yanping Ren and Cong Chen; Supervision: Ping Wang, Lingjuan Man and Li Ma; 
Visualization: Lingjuan Man and Ping Wang; Writing - original draft: Ping Wang; Writing - review and 
editing: Hua Zhang and Zhengpei Yao. All authors read and approved the final manuscript. 
 
 

Ethical approvalEthical approvalEthical approvalEthical approval (for researches involving animals or humans) 
 
Not applicable. 
 
 
AcknowledgementsAcknowledgementsAcknowledgementsAcknowledgements    
 
This work was supported by natural science fondation of xinjiang uygur autonomous rigion  

2022D01D35.    
 
 

Conflict of InterestsConflict of InterestsConflict of InterestsConflict of Interests    
 
The authors declare that there are no conflicts of interest related to this article. 
 
 



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