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IBA、NAA和蔗糖浓度对东北刺人参不定根增殖生长的影响 总被引:4,自引:0,他引:4
【研究目的】为大量扩繁东北刺人参不定根提供可靠的理论依据。【方法】以东北刺人参不定根为外植体,研究在液体振荡培养中,NAA、IBA以及蔗糖浓度对东北刺人参不定根生长的影响。【结果】不同生长素及浓度对东北刺人参不定根的影响中,IBA对促进东北刺人参不定根的生长效果优于NAA,当IBA浓度为3~4 mg/L时,适合不定根生长,培养不定根的IBA浓度为3 mg/L;在培养基MS+IBA 3 mg/L中提高蔗糖浓度到50 g/L时,可明显促进东北刺人参不定根的鲜物重和干物重的增加,分别为5.3、0.49 g。【结论】培养基配方为MS+IBA 3 mg/L+50 g/L蔗糖且振荡培养时,东北刺人参不定根的生长效果最好。 相似文献
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贯叶连翘不定根悬浮培养的初步研究 总被引:1,自引:1,他引:0
为了给贯叶连翘不定根的大量扩繁提供可靠的理论依据,以贯叶连翘不定根为材料进行悬浮培养,对不定根生长的培养基种类、糖种类以及IBA浓度进行优化筛选,再通过观察贯叶连翘不定根的生长情况,测量其鲜物重和干物重,计算干物率和增殖系数,来确定最佳的悬浮培养条件。不同的培养基种类对贯叶连翘不定根的生长影响较大,MS对促进不定根生长的效果最好;蔗糖可明显增加贯叶连翘不定根的鲜物重和干物重,分别为8.29 g、0.46 g;当IBA浓度为1.0 mg/L时,贯叶连翘不定根的鲜物重﹑干物重﹑干物率以及增殖系数均达到最大值,分别为8.98 g﹑0.49 g﹑5.46%和13.97。贯叶连翘不定根在MS+IBA 1.0 mg/L,蔗糖作为其碳源的悬浮培养基中生长,增殖效果最好。 相似文献
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为探讨最适初代诱导、增殖继代生根的培养基配方,建立腊花的组织培养技术体系,以腊花嫩茎尖为实验材料,采用MS培养基,向培养基中添加不同配比组合的KT和NAA,对腊花进行初代诱导培养;设置6-BA和NAA不同激素浓度组合进行增殖培养;选用1/2MS培养基为腊花生根培养的基础培养基,添加IBA不同浓度配比培养实验。最佳初代诱芽培养基为MS+ KT 3.0 mg/L+ NAA 0.2 mg/L+琼脂6.2 g/L+蔗糖30 g/L,pH 5.8,诱导率达88.8%。最佳增殖培养基为MS+ 6-BA 1.0 mg/L+ NAA 0.1 mg/L+ 琼脂6.2 g/L+蔗糖30 g/L,pH 5.8,增殖系数为3.6。最佳生根培养基为1/2MS+ IBA 0.6 mg/L+琼脂6.2 g/L+蔗糖30 g/L+0.1 g/L活性炭,pH 5.8,生根率100%。 相似文献
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为建立诱导油松不定根高频发生的实验系统,研究以组培不定芽和实生苗下胚轴插穗为材料,进行适合油松不定根诱导材料的筛选。在此基础上,以下胚轴为材料,研究子叶、苗龄、不同浓度的植物生长调节物质(IBA、BA)组合以及预处理对其生根的影响。结果表明,油松下胚轴插穗比组培不定芽具有更高的不定根发生潜力;以2周龄实生苗的下胚轴为材料,在1/2 DCR+ 20 g/L蔗糖+ 6 g/L琼脂+ 4 mg/L IBA、pH 5.8的培养基上预培养15天,然后转到去除IBA的相同成分的培养基上继续培养,可以获得较好的生根效果,此条件下生根率最高可达96.67%,这为进一步研究油松不定根发生的相关机理提供了可行的实验体系。 相似文献
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《分子植物育种》2020,(15)
为探讨附子丛生芽的诱导、增殖及不定根诱导条件。本研究以附子带腋芽茎段为外植体,以MS和1/2MS为基本培养基,添加不同浓度的6-BA、NAA、TDZ、IBA等植物生长调节剂,观察附子丛生芽的诱导、增殖、生根情况。结果发现,附子茎段经75%乙醇处理30 s后,0.1%Hg Cl2灭菌10 min,污染率为27.78%,存活率可达84.61%。附子第三个腋芽,诱导率为53.34%,死亡外植体少。丛生芽在MS+6-BA 2 mg/L+NAA0.3 mg/L条件时诱导率为86.67%,芽长1.947 cm,植株茎干粗壮。增殖培养时添加TDZ 2 mg/L+NAA0.3 mg/L,增殖系数达到4.029,苗粗壮,叶片浓绿。生根培养基条件为1/MS+IBA 0.5 mg/L时,15 d的生根率可达100%,平均根长0.906 cm,平均根数10.5条,叶色翠绿,生长旺盛。研究表明,最佳的取材部位为第三个腋芽,丛生芽诱导的最佳培养基为MS+6-BA 2 mg/L+NAA 0.3 mg/L,丛生芽增殖培养基中添加TDZ 2 mg/L+NAA 0.3 mg/L的增殖效果最好,适宜的生根培养基为1/2MS+IBA 0.5 mg/L。本研究为附子快繁体系的建立和工厂化育苗提供了理论依据。 相似文献
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澳洲红树莓的离体培养 总被引:2,自引:2,他引:0
用澳洲红树莓半木质花茎段为外植体,以MS为基本培养基,研究两种激素6-BA和IBA不同浓度组合的芽增殖效应;以1/2MS为基本培养基,研究IBA的生根效果。试验结果表明:澳洲红树莓的最佳分化培养基为MS+6-BA0.8 mg/L+IBA0.1 mg/L+Sugar30 g/L+Agar7 g/L,最有效的生根培养基为1/2MS+IBA0.1 mg/L+Sugar30 g/L+Agar7 g/L。 相似文献
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树莓品种‘Kivigold’快繁技术体系建立 总被引:2,自引:1,他引:1
以树莓(Rubus idaeus)品种‘Kivigold’带腋芽茎段为外植体,研究消毒剂HgCl2(0.1%)不同的消毒时间对外植体培养的影响,对不定芽增殖培养基和生根培养基中适宜的激素种类及浓度、生根苗移栽驯化中适宜的基质进行了筛选。结果显示,树莓品种‘Kivigold’外植体的最佳消毒时间为10 min,初代培养时只需添加6-BA即可满足外植体萌发和生长的需要;在不定芽增殖过程中,细胞分裂素主要影响不定芽的增殖,而生长素主要影响不定芽的生长,以质量浓度低于1.5 mg/L的6-BA以及质量浓度低于0.5 mg/L的NAA较为适宜,3种碳源中蔗糖更有利于不定芽的增殖和生长;经过进一步的筛选,确定适宜于‘Kivigold’不定芽增殖和生长的培养基为MS+1.00 mg/L 6-BA +0.10 mg/L NAA(含20 g/L蔗糖和5.9 g/L琼脂,pH 5.8),适宜于‘Kivigold’不定芽生根的培养基为1/2 MS+0.10 mg/L NAA(含20 g/L蔗糖和5.9 g/L琼脂,pH 5.8);在移栽驯化中最适宜的栽培基质为泥炭土:珍珠岩=1:1,移栽成活率可达到93.33%。 相似文献
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以新疆杨叶片为外植体,研究新疆杨组织培养再生体系建立的主要影响因素。结果表明:诱导愈伤组织的最佳培养基组合为MS+0.5 mg/L 6-BA+0.5 mg/L 2,4-D;愈伤组织分化的最佳培养基组合为MS+0.1 mg/L TDZ+0.3 mg/L IBA,不定芽增殖的最佳培养基组合为MS+1.0 mg/L 6-BA+0.3 mg/L IBA,诱导生根的最佳培养基组合为1/2MS+0.5 mg/L IBA,新疆杨组培苗在生根培养基上形成的根条数多,苗体健壮,生根率达到100%。本研究成功建立了新疆杨组织培养再生体系,为其转基因研究工作奠定了基础。 相似文献
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K. Bürcky 《Journal of Agronomy and Crop Science》1993,171(3):153-160
Influence of nitrogen supply on water consumption and dry matter production of sugar beet in pot experiments
This paper describes the influence of nitrogen on water consumption, dry matter production and water use efficiency (WUE) of sugar beet.
The experiments, conducted in 1988 and 1989 using sand culture in pots, included five nitrogen levels from 2 to 16 g/pot.
Beet roots were heaviest where the N-supply was 8 g/pot. Top weight increased considerably up to 16 g N/ pot. Therefore plant dry weight was greatest where the N-supply was maximum. Overall, in 1989 dry matter production (g/pot) was 20 % greater than in 1988 because the beet roots were heavier.
Water consumption increased with nitrogen supply. At the largest N-doses water consumption was 110 1 (1988) and 140 1 (1989). This was three times the amount used at the smallest N-supply. Over the whole season WUE was greatest at 4 g N/pot and lower at both extremes of N-supply. Independently of N-supply, production of plant dry matter per litre of water consumed was between 4.9 and 6.0 g. For root dry matter, equivalent values were 3.7 and 4.6 g/l, and for white sugar yield they were 2.3 and 3.1 g/1 相似文献
This paper describes the influence of nitrogen on water consumption, dry matter production and water use efficiency (WUE) of sugar beet.
The experiments, conducted in 1988 and 1989 using sand culture in pots, included five nitrogen levels from 2 to 16 g/pot.
Beet roots were heaviest where the N-supply was 8 g/pot. Top weight increased considerably up to 16 g N/ pot. Therefore plant dry weight was greatest where the N-supply was maximum. Overall, in 1989 dry matter production (g/pot) was 20 % greater than in 1988 because the beet roots were heavier.
Water consumption increased with nitrogen supply. At the largest N-doses water consumption was 110 1 (1988) and 140 1 (1989). This was three times the amount used at the smallest N-supply. Over the whole season WUE was greatest at 4 g N/pot and lower at both extremes of N-supply. Independently of N-supply, production of plant dry matter per litre of water consumed was between 4.9 and 6.0 g. For root dry matter, equivalent values were 3.7 and 4.6 g/l, and for white sugar yield they were 2.3 and 3.1 g/1 相似文献
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为提高石榴叶片再生率,增加再生芽数量及缩短再生周期,以‘泰山红’‘、泰山三白甜’‘、皮亚曼’‘、牡丹’4个石榴品种盆栽苗和无菌苗叶片为试材,研究培养基类型、生长调节剂配比、叶片来源和培养步骤对不定芽再生的影响。结果表明:MS是叶片再生最适培养基类型;无菌苗叶片比盆栽苗叶片更易再生不定芽;BA3.0mg/L+KT1.0mg/L+IBA0.3mg/L是叶片愈伤组织诱导、分化和不定芽形成过程中生长调节剂最佳配比;先在液体培养基上培养3~5天,再转至固体培养基比仅在固体培养基上效果更好,叶片再生率最高达98.47%,出芽数达7.51个。叶片不定芽的最佳单芽培养基和增殖培养基分别为B5+BA0.6mg/L+IBA0.5mg/L+椰汁100mL/L+PVP2.0g/L+GA31.0mg/L和B5+BA0.8mg/L+IBA0.5mg/L+椰汁100mL/L+PVP2.0g/L,增殖系数为5.56。适宜的生根培养基为B5+IBA1.0mg/L+椰汁100mL/L,生根率为89.63%。由此建立了石榴叶片高频再生体系。 相似文献
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卷丹百合脱毒快繁技术研究 总被引:3,自引:1,他引:2
对卷丹百合脱毒苗组培快繁技术体系进行研究。以带LSV病毒的卷丹百合珠芽为材料,通过36℃高温预处理10天,剥取0.2mm大小的茎尖在MS+2.5mg/L6-BA+1.5mg/LGA+0.5mg/LNAA+0.1g/L活性炭+0.6%琼脂+3%白糖的培养基中进行芽诱导培养,经过一次继代培养后,用RT-PCR检测LSV病毒,脱毒率达100%。将脱毒百合苗在MS+2.0mg/L6-BA+2.0mg/L2,4-D+0.1mg/LNAA培养基中诱导愈伤组织及丛生芽,诱导率达100%;在1/2MS+2.5mg/L6-BA+0.2mg/LNAA培养基中进行分化、增殖培养,增殖倍数达到4.31;采用MS+1.2mg/LNAA+0.5g/L活性炭培养基进行生根培养,产生的根系多而粗壮,移栽时最易成活。 相似文献