Morphological Structure of Vessel Elements of Prunes L. from Northeast Area of China

doi:10.7525/j.issn.1673-5102.2021.01.002

Abstract

Abstract:

The scanning electron microscopy（SEM） and resin casting method were used to observe the micromorphological characteristics of vessel molecular types， pits and perforation plates of ten species of Prunus L. in Northeast of China， and the quantitative data of lumen length， width， tail length and end wall angle were measured. The conduit type， tail length and perforation plate type of the same species were stable in different habitats， and did not change with the change of habitats. There were three types of ducts in ten species of Prunus L.， including spiral， pitted and reticulate. In addition to P.ussuriensis Kov. et Kost.， P.humilis（Bge.） Sok. and P.sibirica（L.）Lam.， there are only two types of vessels， including pitted and reticulate. Three types are common in the other seven plants. Helical thickening is common in this genus of conduit molecules. The single perforation plate is common in the plum plants， only in P.maximowiczii（Rupr.） Kom.， P.tomentosa（Thunb.） Wall. and P.salicina Lindl.. Only in P.racemosa（Lam.）Gilib. and P.ussuriensis Kov. et Kost. and P.japonica（Thunb.） Lois. and P.sibirica（L.）Lam.， the relatively primitive opposite-alternate pitting was observed， and the other six patterns were all alternate pitting. The lumen length， width and end wall area were significantly related to the habitat. The measurement of the tail length shows that the tail length of the vessel elements of the same plant is relatively stable in different habitats， almost unchanged， which can be used in micro plant taxonomy.

Key words: Prunes L., vessel elements, SEM, morphological structure

CLC Number:

S662.3

Zi-Yu ZOU, Li-Wei GU, Da-Wei ZHANG. Morphological Structure of Vessel Elements of Prunes L. from Northeast Area of China[J]. Bulletin of Botanical Research, 2021, 41(1): 4-12.

Figures/Tables 4

Table 1

Experimental material information

种名Species	采集地Locality	生境Habitat
稠李 P.racemosa(Lam.)Gilib.	黑龙江省伊春市Yichun City	海拔283 m的林地内Forest，altitude 283 m
	吉林省安图县Antu County	海拔407 m的杂木林内Shaw，altitude 407 m
	辽宁省营口市Yingkou City	海拔11 m的灌丛内Shaw，altitude 11 m
斑叶稠李 P.maackii(Rupr.) Kom.	黑龙江省饶河县Raohe County	海拔57 m的田地内Field，altitude 57 m
	吉林省敦化市Dunhua city	海拔756 m的灌丛内Shaw，altitude 765 m
	吉林省安图县Antu County	海拔423 m的河岸上river bank，altitude 423 m
东北李 P.ussuriensis Kov.et Kost.	吉林省临江市Linjiang City	海拔149 m的山林内Forest，altitude 149 m
	本溪市Benxi City	海拔249 m的岩石坡上Rock slope,altitude 249 m
	大连市Dalian city	海拔171 m山地Mountain， altitude 171 m
李 P.salicina Lindl.	伊春市带岭Yichun city belt	海拔221 m的林地内Forest，altitude 221 m
	帽儿山Maor mountain	海拔670 m的山林内Forest，altitude 670 m
	本溪市Benxi City	海拔248 m山地Mountain， altitude 248 m
榆叶梅 P.triloba(Lindl.) Ricker	东北林业大学林场Northeast Forestry University	海拔136 m的林地内Forest，altitude 136 m
	长白山Paekdusan	海拔1 667 m的山林内Forest，altitude 1 667 m
	本溪市Benxi City	海拔249 m的林地内Forest，altitude 249 m
黑樱桃 P.maximowiczii(Rupr.) Kom.	伊春市带岭Yichun city	海拔221 m的林地内Forest，altitude 221 m
	安图县Antu County	海拔249 m的林地内Forest，altitude 249 m
	辽宁省营口市Yingkou City	海拔10 m的灌丛内Shaw，altitude 10 m
欧李 P.humilis(Bge.) Sok.	帽儿山Maor mountain	海拔670 m的山林内Forest，altitude 670 m
	长白山Paekdusan	海拔2 014 m的山林内Forest，altitude 2 014 m
	鞍山市Anshan City	海拔32 m山地Mountain，altitude 32 m
毛樱桃 P.tomentosa(Thunb.) Wall.	东北林业大学林场Northeast Forestry University	海拔136 m的林地内Forest，altitude136 m
	安图县Antu County	海拔131 m的林地内Forest，altitude 131 m
	大连市Dalian city	海拔64 m山地Mountain， altitude 64 m
郁李 P.japonica(Thunb.) Lois.	东北林业大学林场Northeast Forestry University	海拔136 m的林地内Forest，altitude136 m
	长白山Paekdusan	海拔1 451 m的山林内Forest，altitude 1 451 m
	辽宁省营口市Yingkou City	海拔15 m的田地内Field，altitude 11 m
山杏 P.sibirica(L.)Lam.	东北林业大学林场Northeast Forestry University	海拔136 m的林地内Forest，altitude136 m
	长白山Paekdusan	海拔1 784 m的山林内Forest，altitude 1 784 m
	鞍山市Anshan City	海拔32 m山地Mountain， altitude 32 m

Table 1

Fig.1

Table 2

References 26

1	傅沛云.东北植物检索表：2版［M］.北京：科学出版社，1995：81-160.
	Fu P Y.Plant search form of China northeast：2nd ed［M］.Beijing：Science Press，1995：81-160.
2	中国科学院中国植物志编辑委员会.中国植物志［M］.北京：科学出版社，1979：1-40．
	Editorial Board of Chinese Botany，Chinese Academy of Sciences.Flora of Chinese［M］.Beijing：Science Press，1979：1-40．
3	俞德浚.关于核果类植物分类的初步意见［J］.中国果树，1959，（5）：35-38.
	Yu D J.A preliminary opinion on the classification of drupe plants［J］.China Fruits，1959，（5）：35-38.
4	Lotova L I，Timonin A C.Anatomy of cortex and secondary phloem of Rosaceae.12.Prunoideae［J］.Botanicheskiy Zhurnal，2002，87（5）：68-82.
5	Zhang S Y.Systematic wood anatomy of the Rosaceae［J］.Blumea，1992，37（1）：81-158.
6	Challice J S.Rosaceae chemotaxonomy and the origins of the Pomoideae［J］.Botanical Journal of the Linnean Society，1974，69（4）：239-259.
7	Cevallos-Ferriz S R S，Stockey R A.Fruits and seeds from the princeton chert（Middle Eocene） of British Columbia：Rosaceae（Prunoideae）［J］.Botanical Gazette，1991，152（3）：369-379.
8	Ma R C，Oliveira M.Evolutionary analysis of S-RNase genes from Rosaceae species［J］.Molecular Genetics and Genomics，2002，267（1）：71-78.
9	尹秀玲，王金侠，邵建睛，等.蔷薇科9属12种代表植物导管类型的解剖学观察［J］.河北科技师范学院学报，2006，20（4）：14-17.
	Yin X L，Wang J X，Shao J J，et al.The anatomy observation of the vessel type of the twelve kinds of plants in Rosaceae［J］.Journal of Hebei Normal University of Science & Technology，2006，20（4）：14-17.
10	郭学民，李娜，刘建珍，等.毛樱桃嫁接‘美早’甜樱桃小脚现象的导管分子特性研究［J］.果树学报，2017，34（3）：321-328.
	Guo X M，Li N，Liu J Z，et al.Vessel element characteristics of scion overgrowing of the sweet cherry variety ‘Tieton’ grafted on Cerasus tomentosa［J］.Journal of Fruit Science，2017，34（3）：321-328.
11	胡蓉，林沙.樱桃和日本晚樱茎次生木质部导管分子比较研究［J］.内江师范学院学报，2017，32（12）：83-88.
	Hu R，LIN S.Comparative anatomy of secondary xylem in the stem of Cerasus Pseudocerasus and Cerasus Serrulata var.Lannesiana［J］.Journal of Neijiang Normal University，2017，32（12）：83-88.
12	高建平，王彦涵，陈道峰.不同产地华中五味子叶表皮结构和导管分子的解剖学特征及其与环境因子的关系［J］.西北植物学报，2003，23（5）：715-723.
	Gao J P，Wang Y H，Chen D F.Anatomical characteristics of leaf epidermis and vessel elements of Schisandra sphenanthera from different districts and their relationships to environmental factors［J］.Acta Botanica Boreali-Occidentalia Sinica，2003，23（5）：715-723.
13	张大维，石福臣.黑龙江桦木科植物导管分子解剖学研究［J］.植物研究，2004，24（2）：158-161.
	Zhang D W，Shi F C.Morphologyical anatomical studies on Betulaceae vessel element from Helongjiang Province，China［J］.Bulletin of Botanical Research，2004，24（2）：158-161.
14	张大维，邢怡，党安志.黑龙江槭树属植物导管分子解剖学研究［J］.植物研究，2007，27（4）：408-411.
	Zhang D W，Xing Y，Dang A Z.Morphological anatomical studies on Aceraceae vessel element from Heilongjiang Province，China［J］.Bulletin of Botanical Research，2007，27（4）：408-411.
15	Carlquist S，Schneider E L.Origin and nature of vessels in monocotyledons.5.Araceae subfamily Colocasioideae［J］.Botanical Journal of the Linnean Society，1998，128（1）：71-86.
16	Carlquist S.Wood anatomy of Coriariaceae：phylogenetic and ecological implications［J］.Systematic Botany，1985，10（2）：174-183.
17	王占武，王娜，刘强，等.樱桃和榆叶梅导管的比较研究［J］.吉林师范大学学报：自然科学版，2013，34（4）：84-86.
	Wang Z W，Wang N，Liu Q，et al.Comparative studies on vessel of Cerasus tomentosa and Amygdalus triloba［J］.Journal of Jilin Normal University：Natural Science Edition，2013，34（4）：84-86.
18	Carlquist S，Schneider E L.SEM studies on vessels in ferns.16.Pacific tree ferns（Blechnaceae，Cyatheaceae，Dicksoniaceae）［J］.Pacific Science，2000，54（1）：75-86.
19	喻诚鸿.次生木质部的进化与植物系统发育的关系［J］.植物学报，1954，3（2）：183-196.
	Yu C H.The relationship between the evolution of secondary xylem and plant system development［J］.Bulletin of Botany，1954，3（2）：183-196.
20	朱广龙，邓荣华，马茵，等.酸枣茎导管对自然梯度干旱生境响应的结构特征［J］.生态学报，2015，35（24）：8268-8275.
	Zhu G L，Deng R H，Ma Y，et al.Changes in the vessel morphology of Ziziphus jujuba var.spinosa plants in response to natural drought-gradient ecotopes［J］.Acta Ecologica Sinica，2015，35（24）：8268-8275.
21	李红芳，田先华，任毅.维管植物导管及其穿孔板的研究进展［J］.西北植物学报，2005，25（2）：419-424.
	Li H F，Tian X H，Ren Y.Research progress in vessel and perforation plate of vascular plants and some considerations for future research［J］.Acta Botanica Boreali-Occidentalia Sinica，2005，25（2）：419-424.
22	刘树焕，谷利伟，张大维.黑龙江苹果亚科5属14种植物导管分子形态结构研究［J］.西北植物学报，2015，35（4）：723-729.
	Liu S H，Gu L W，Zhang D W.Morphological structure of vessel elements in 14 species of Maloideae （Rosaceae） from Heilongjiang，China［J］.Acta Botanica Boreali-Occidentalia Sinica，2015，35（4）：723-729.
23	李荣，党维，蔡靖，等.6个耐旱树种木质部结构与栓塞脆弱性的关系［J］.植物生态学报，2016，40（3）：255-263.
	Li R，Dang W，Cai J，et al.Relationships between xylem structure and embolism vulnerability in six species of drought tolerance trees［J］.Chinese Journal of Plant Ecology，2016，40（3）：255-263.
24	杨淑敏，江泽慧，任海青，等.13种沙生植物纤维和导管分子长度变异的研究及木质部特征的定量研究［J］.植物研究，2007，27（5）：601-606.
	Yang S M，Jiang Z H，Ren H Q，et al.Quantitative characteristics of xylem cells and variation in vessel element length and fibre length for 13 Psammophytes［J］.Bulletin of Botanical Research，2007，27（5）：601-606.
25	Jansen S，Baas P，Gasson P，et al.Variation in xylem structure from tropics to tundra：Evidence from vestured pits［J］.Proceedings of the National Academy of Sciences of the United States of America，2004，101（23）：8833-8837.
26	Benkova V E，Nekrasova A A.Wood anatomy of Rosaceae plants from Northern Siberia.1.Spiraeoideae and Maloideae［J］.Botanicheskii Zhurnal-Moskva Then sankt-Peterburg-，1998，83（2）：47-54.

种名 Species	螺纹加厚 Helical thickening	导管形态类型 Type of vessels			纹孔排列方式 Type of pits		穿孔板类型 Type of perforation plates
种名 Species	螺纹加厚 Helical thickening	螺纹导管 Spiral	孔纹导管 Pitted	网纹导管 Reticulate	对列式 Opposite pitting	互列式 Alternate pitting	梯状穿孔板 Scalariform	单穿孔板 Simple
稠李P.racemosa(Lam.)Gilib.	+	+	+	+	+	+	-	+
斑叶稠李P.maackii(Rupr.) Kom.	+	+	+	+	-	+	-	+
东北李P.ussuriensis Kov.et Kost.	+	-	+	+	+	+	-	+
李P.salicina Lindl.	+	+	+	+	-	+	-	+
榆叶梅P.triloba(Lindl.) Ricker	+	+	+	+	-	+	-	+
黑樱桃P.maximowiczii(Rupr.) Kom.	+	+	+	+	-	+	+	+
欧李P.humilis(Bge.) Sok.	+	-	+	+	-	+	-	+
毛樱桃P.tomentosa(Thunb.) Wall.	+	+	+	+	-	+	+	+
郁李P.japonica(Thunb.) Lois.	+	+	+	+	+	+	+	+
山杏P.sibirica(L.)Lam	+	-	+	+	+	+	-	+

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