植物组织培养简报摘编

幼花轴在(1)上10天左右产生白色愈伤组织,转入(2)后一个月左右形成大量不定芽,并可在(2)上继代扩增。具芽地下茎在(3)上培养半个月后,基部产生少量白色愈伤组织,转入(4)上产生芽丛,芽丛基部愈伤组织具有分化不定芽能力。上述幼苗长出2—3幼叶后,移到(5)中诱导生根,一个月后移栽成活。国内外未见报道。     

长时期保持高频率再生能力的同源四倍体水稻花粉无性系的建立

同源四倍体水稻杂种花药离体培养,建立了一个高频率再生植株能力的花粉无性系A87203 4C-1-5。试验结果表明:一个芽丛培养一个月,芽数增殖频率为150—200倍。芽的发生方式为芽上生芽。若将芽丛剪碎,重新接在 MS 诱导培养基上,愈伤组织重量的增殖率为5.0倍左右。再将愈伤组织转入 MS 分化培养基上,大约有50%愈伤组织块又可分化出芽,并且仍具有高频率再生芽的特性。继代培养30多代(一年多时间)后仍保持旺盛的增殖能力。通过控制光温条件,可迅速再生植株。植株移栽田间,大多数生长正常,少量外部形态变异。细胞学鉴定,6株为三体(2n 1=25)。     

枸杞髓组织离体培养及高频率植株再生的研究

枸杞髓组织在４种ＭＳ培养基上都能诱导出愈伤组织,诱导率５３．７％～１００％。在培养基ＭＳ＋６－ＢＡ０．１ｍｇ／Ｌ＋ＮＡＡ０．５ｍｇ／Ｌ获得的愈伤组织,呈颗粒状,分散性能好,胚性细胞多．将其转移到ＭＳ＋６－ＢＡ０．５ｍｍ／Ｌ＋ＮＡＡ０．０１ｍｇ／Ｌ的分化培养基上获得大量绿色小芽,小芽在ＭＳ＋６－ＢＡ０．２ｍｇ／Ｌ的培养基上得到快速繁殖,繁殖系数５０～１５０株／芽·月。丛生芽在ＭＳ＋ＮＡＡ０．２ｔｍｇ／Ｌ的培养基上形成完整植株     

碱蓬茎段培养再生植株的研究

将碱蓬（ＳｕａｅｄａＦｏｒｓｋ）种子经消毒后分别接种在４种不同ｐＨ值的培养基上,两天后观察发现以ｐＨ７培养基上的种子出苗最快,出苗率最高。６ｄ时观察,在ｐＨ９的培养基上也有较高的出苗率。用上述无菌苗茎段为外植体,分别接种在４种不同生长素的培养基上均能产生愈伤组织,除含有２,４Ｄ的培养基外,其它３组愈伤组织的诱导频率均达到１００％。把愈伤组织移到添加ＢＡＰ与ＩＡＡ的分化培养基上,三个星期后由愈伤组织分化出不定芽,分化频率为１２５％。当不定芽长至１５ｃｍ～２ｃｍ时转入生根培养基,两个星期后长出白色的根,获得完整植株。     

碱蓬茎段培养再生植株的研究

将碱蓬(Suaeda Forsk)种子经消毒后分别接种在4种不同pH值的培养基上,两天后观察发现以pH 7培养基上的种子出苗最快,出苗率最高。6d时观察,在pH9的培养基上也有较高的出苗率。用上述无菌苗茎段为外植体,分别接种在4种不同生长素的培养基上均能产生愈伤组织,除含有2,4-D的培养基外,其它3组愈伤组织的诱导频率均达到100％。把愈伤组织移到添加BAP与IAA的分化培养基上,三个星期后由愈伤组织分化出不定芽,分化频率为12.5％。当不定芽长至1.5cm~2cm时转入生根培养基,两个星期后长出白色的根,获得完整植株。     

枸杞花药愈伤组织悬浮培养条件下胚状体发生与植株再生

采用枸杞花药进行离体培养,建立细胞系,诱导植株再生,结果在含不同激素的4种培养基上都诱导出了愈伤组织,诱导率为17%～169%。愈伤组织在MS 2,4D05mg/L的固体培养基上,经2～3次培养后,获颗粒状胚性愈伤组织,颗粒状胚性愈伤组织转入含相同成分的液体培养基中进行振荡培养,24h后获得大量单细胞。单细胞液经过多次继代培养,建立起稳定的悬浮系。悬浮细胞在液体培养基中培养8～10d可获得含有大量胚状体的愈伤组织块,收集悬浮培养物转移到MS 6BA02mg/L的固体培养基上,胚状体能够萌发形成大量绿色小芽,小芽转入生根培养基(MS NAA02mg/L)中20d后得到完整植株。植株根尖细胞经细胞学鉴定为单倍体。     

植物组织培养简报摘编

1.叶片切段在(1)上培养,先出现白点,以后白点处向上鼓起形成白色或淡绿色突起的愈伤组织,继代几次后,愈伤组织变成淡绿色,并可直接长出绿色嫩芽。如把愈伤组织转入(3)上继代培养,在每块愈伤组织上生出数个健壮的芽丛。     

欧当归原生质体培养中体细胞胚胎发生和细胞学变化

从继代培养的欧当归(Levisticum officinale Koch)愈伤组织分离的原生质体在 C81V培养基中培养,得到了较高频率的持续分裂。形成的细胞团转移到固体培养基上后,发展成了白色松软型的愈伤组织。将其转移到附加6-苄氨基嘌呤和吲哚丁酸的 N6培养基上继续培养了2—3个月后,表面出现了浅黄色、颗粒状的胚性愈伤组织。后者在附加吲嗓丁酸和萘乙酸的 MS 培养基上培养,可通过体细胞胚胎发生途径分化出大量小植株。对供体愈伤组织和原生质体再生植株进行了细胞学观察。     

大豆顶芽组织培养植株再生的研究

栽培大豆(Glycine max)6个品种顶芽组织培养植株再生中,以铁丰18形成愈伤组织的能力最强,在B_5附加2,4-D 1.0mg/L,BA 0.5mg/L的培养基上,诱导率可达80％左右。愈伤组织出现10d后及时转移到MS附加BA 1.0,KT0.5,ZT0.5和IAA0.5mg/L的分化培养基上,分芽化的频率达40％左右。切割的不定芽在1/2MS基本培养基附加IBA 0.2～0.5mg/L、蔗糖2％的琼脂培养基上,可诱导生根,长成完整小植株。     

马铃薯器官发生和植株再生研究

虎头、克４和Ｆａｖｏｒｉｔａ３个马铃薯品种的根、茎、叶外植体在附加ＮＡＡ和ＢＡ各１ｍｇ／Ｌ的ＭＳ培养基上诱导出愈伤组织。在附加０．２ｍｇ／ＬＮＡＡ和１ｍｇ／ＬＢＡ的ＭＳ培养荐,愈伤组织上分化产生不定芽。１．５－２．５ｃｍ高的不定芽在ＭＳ＋０．０５ｍｇ／ＬＮＡＡ培养基上生根形成再生完整植株。３个马铃薯品种中,虎头茎的愈伤组织诱导频率最高,达９８％。Ｆａｖｏｒｉｔａ叶愈伤组织的不定芽分化频率和不定芽生     

高效诱导冬瓜再生植株的研究

将台湾冬瓜的种子接种于pH值为7.2的1/2MS培养基上预培养,5d左右种子即可萌发,萌发率为100%,幼苗生长正常。切取预培养15-20d的无菌幼苗的茎尖和带腋芽的茎段接种于MS 1mg/LNAA 4mg/L6-BA培养基上,10d左右在茎尖和茎段（带腋芽）切口处长出愈伤组织,30d左右在愈伤组织处分化出丛生芽,丛生芽的诱导频率接近95%,繁殖系数25.6。将小芽切下转入不加任何生长调节剂MS培养基上,培养几天后芽逐渐长大,并在芽的基部长出白色根系。选取生长健壮的试管苗经过炼苗后移栽到大田中,生长良好。     

Stem Apex Culture and Quality Improvement of Tubercles of Pinellia ternata

Formation of Plantlets was achieved when stem apex of Pinellia ternata Brier. Cultured in vitro on MS medium with KT 0. 5 mg/L + NAA 0.2 mg/L (MSI). With petioles of the plantlet as explants callus could be induced after cultured for a week on MS medium with 2, 4-D 2.0 mg/L + KT 0.5 mg/L (MSII). Calli were subcultured once in every month. After 3--4 months a kind of friable calli could be selected, from which the tubercles could be differentiate and the plantlets formed when transfered onto MSI. But before callus differentiation, a lot of roots were formed on callus. The plantlets could be produced directly from the petiole segment. It was found that the stem growing tip was always covered by the leaf primordium and the former leaf primordium was covered by the latter leaf primordium during the differentiation of the apical bud of tubercle. The frenquency of plantlet differentiation from callus and petioles was over 70%. The rate of regeneration of plantlet on liquid static culture was twice as much as that on solid culture. All plantlets grew well after being transfered into the plot. The fresh weight of tuber-plant was 103 % higher than that of control (cultivated plant come from tubers). The alkaloid content of tubers come from tuberplant was 0. 344%, that of control was 0. 203% and 0. 264% for the wild tuber.     

江西铅山红芽芋脱毒苗球茎愈伤组织诱导及其再生体系的建立

以江西铅山红芽芋脱毒苗为试材,研究不同因素对红芽芋脱毒苗球茎愈伤组织诱导及其再生体系的影响,以期对红芽芋脱毒苗的再生体系进行优化。结果表明,红芽芋脱毒苗球茎愈伤组织诱导的最佳培养基是MS+TDZ 2 mg·L^-1+2,4-D 1 mg·L^-1。红芽芋脱毒苗球茎愈伤组织分化的最佳培养基是MS+TDZ 2 mg·L^-1+NAA 1 mg·L^-1。红芽芋脱毒苗不定芽生根的最佳培养基是1/2MS+NAA 0.5 mg·L^-1+PP₃₃₃ 0.5 mg·L^-1。红芽芋再生苗最好的移栽基质为发酵后的腐锯木屑。红芽芋脱毒苗球茎愈伤组织再生苗移栽时最佳的PP₃₃₃浓度为20～50 mg·L^-1。本试验成功建立了红芽芋脱毒苗球茎愈伤组织的再生体系,为红芽芋脱毒苗转基因的研究和种质创新奠定了基础。     

绿萝叶片的组织培养

绿萝(Epipremnum aureum (Linden et Andr)Bunting)系天南星科(Araceae)麒麟叶属(Epipremnum)的一种木质藤本植物,常攀援于山石上、墙壁上或它树上附生,分枝多,枝悬垂,园艺上用作荫棚悬挂植物。绿萝的叶片薄革质,翠绿色,一般(特别是叶面)有多数不规则的黄色斑块,极为美丽,它不仅是庭园观赏植物,而且还可折枝插瓶,经久不萎。本种不易开花,通常都是无性扦插繁殖。迄今为止,关     

High Frequency Plant Regeneration from Astragalus melilotoides hypocotyl and stem explants via somatic embryogenesis and organogenesis

An efficient and reproducible procedure is established for the plant regeneration from hypocotyl explants and hypocotyl-or stem-derived calli in Astragalus melilotoides. High frequency somatic embryo formation (98.3%) occurred direct on hypocotyls on Murashige and Skoog (MS) medium supplemented with 2.69 µM NAA and 4.44 µM BA within 5 weeks. Three types of calli were induced from the hypocotyl and stem segments on MS medium containing 9.05 µM 2,4-D and 2.22–4.44 µM BA. Both somatic embryos and adventitious buds were initiated from hypocotyl-derived calli while only adventitious buds were formed from stem-derived calli in MS medium supplemented with 2.69 µM NAA and 4.44–8.89 µM BA. Somatic embryos or adventitious buds developed into plantlets following being cultured for 3 weeks on MS medium without any growth regulators or with 14.78 µM IBA, respectively. All the regenerated plants were normal with respect to morphology and growth characters, and produced fertile seeds after planting in soil.     

An Efficient Protocol for Plantlet Regeneration via Direct Organogenesis by Using Nodal Segments from Embryo-Cultured Seedlings of Cinnamomum camphora L.

A simple and efficient plantlet regeneration protocol via direct organogenesis was established for camphor tree (Cinnamomum camphora L.). Stem segments with one node (SN explants) from embryo-cultured seedlings (EC seedlings) were used as explants. Murashige and Skoog (MS) medium supplemented with 0.5 mg/L 2, 4-dichlorophenoxyacetic acid and 2.0 mg/L 6-benzyladenine was used to induce cotyledonary embryo germination. This medium was also used for EC seedlings propagation and adventitious bud induction from SN explants. Regenerated plantlets were cultured on hormone-free MS medium for elongation and root induction. The regeneration capability of SN explants was compared by using EC seedling lines established in this research. EC seedling line EL6 exhibited the highest adventitious bud induction frequency (91.7%) and the highest number of buds per responding explant (5.2), which was considered as the most efficient EC seedling line for further gene transformation research.     

Plant regeneration from seedling explants of green bean (Phaseolus vulgaris L) via organogenesis

Green bean (Phaseolus vulgaris L.) plants were regenerated from 3-day old seedling explants via organogenesis. The explants contained a cotyledon and a small portion (2–3 mm) of embryonic axis split in half. Explants were cultured on a defined medium containing glutamine as the sole nitrogen source. A ring of meristematic tissue was produced at the base of the axillary bud located at the cotyledonary node. The meristematic tissue was produced only if the axillary bud was present together with the cotyledon in the explant. Buds and shoots developed from the meristematic ring. Selected shoots produced roots when excised from the cluster of buds and transferred to root induction medium. Rooted shoots (plantlets) grew well and produced viable seeds when grown in the greenhouse. Histological studies revealed the origin of buds from the peripheral layers of the meristematic ring.Production of buds and shoots was a continuous process, so that new shoots could be removed from the explant for plantlet production every 10–14 days. With the cultivar Dark Red Kidney, an average of 49 buds and 8 shoots were regenerated per explant by 30 days after culture initiation. Sixty-seven percent of the shoots produced roots, and 90–95% of the plantlets survived greenhouse acclimatization to produce healthy plants.     

黄槐叶片培养过程中器官发生的研究

以黄槐（ＣａｓｓｉａｓｕｒａｔｔｅｎｓｉｓＢｕｒｍ．ｆ．）幼嫩叶片为材料,接种于ＭＳ＋ＮＡＡ１ｐｐｍ＋２,４－Ｄ１ｐｐｍ＋６－ＢＡ２ｐｐｍ的培养基上,诱导形成两种形态的愈伤组织,即致密愈伤组织与雪花状愈伤组织．将愈伤组织转移到ＭＳ＋ＮＡＡ：１ｐｐｍ＋６－ＢＡ２ｐｐｍ的分化培养基上．仅致密型愈伤组织经过球状体至不定芽途径形成大量再生植株。扫描电镜及组织细胞学观察表明,致密愈伤组织表层细胞排列紧密,有许多分生细胞团,而雪花状愈伤组织表层细胞薄壁化,分裂能力很低。球状体起源于致密愈伤组织表层的分生细胞团,其细胞有极强的分生能力,顶端可以分化发育成不定芽原基,最后形成不定芽并发育成小植株。球状体可以看成是具有形成不定芽能力的繁殖单位．     

Shoot Organogenesis from Immature Zygotic Embryo Cultures of Ginkgo biloba

Immature zygotic embryos were cultured on Murashige and Skoog's medium (MS) supplemented with various combinations of 2,4-dichlorophenoxyacetic acid (2,4-D), naphthaleneacetic acid (NAA), benzyladenine (BA) and zeatin or with various concentrations of 2,4-D alone. The maximum number (8 per embryo) of adventitious buds formed from cotyledons of heart stage embryos cultured on MS medium with 1 mg dm⁻³ BA and 0.01 mg dm⁻³ NAA. The adventitious buds originated from procambial strands of immature embryo cotyledons and then developed into adventitious bud primordia within 20 d. Adventitious buds transferred to hormone free MS medium grew into shoots, but did not produce plantlets because the shoots failed to root. This revised version was published online in July 2006 with corrections to the Cover Date.     

爪哇三七组织培养植株再生

本文报道了爪哇三七通过组织培养再生植株的方法。爪哇三七的叶片,叶柄或茎段外植体分别接种于6种分化培养基上,均难以直接分化。在附加1mgL~(12),4-D和0.1mgL~(-1)KT的B_5培养基上的叶片形成无色疏松的愈伤组织转接于MS附加1mgL~(-1)BAP和0.1mg L~(-1)NAA培养基上,5天后开始形成绿色球胚状结构,继而形成不定芽或丛生芽。这些不定芽或丛生芽在锈根培养基中迅速长成根系发达的完整植株。此外,本试验比较了不同浓度及不同组合的激素对爪哇三七外植体的脱分化、再分化的影响。并讨论了此项工作对柑桔裂皮病类病毒(简称CEV)的复制及致病机理研究的意义。