[Objective] This study aimed to investigate the effects of different salt concentrations on the root vitality of Limonium bicolor (Bunge) Kuntze. [Method] Limonium bicolor (Bunge) Kuntze was treated with 0, 100, 2...[Objective] This study aimed to investigate the effects of different salt concentrations on the root vitality of Limonium bicolor (Bunge) Kuntze. [Method] Limonium bicolor (Bunge) Kuntze was treated with 0, 100, 200 and 400 mmol/L NaCl, respectively. After two weeks, root vitality, biomass and other physiological indicators were measured. [Result] Salt stress had significant influences on the growth of roots. Root vitality of Limonium bicolor increased firstly and reduced gradually with the increase of salt concentration. [Conclusion] The results indicate that Limonium bicolor has certain salt tolerance ability at low salt concentrations; under relatively high salt concentrations, Limonium bicolor roots can maintain high vitality; however, with the continuous increase of salt concentration, Limonium bicolor roots are damaged, with decreasing vitality.展开更多
Sucrose nonfermenting-related protein kinase 1(SnRK1)is one of the critical serine/threonine protein kinases.It commonly mediates plant growth and development,cross-talks with metabolism processes and physiological re...Sucrose nonfermenting-related protein kinase 1(SnRK1)is one of the critical serine/threonine protein kinases.It commonly mediates plant growth and development,cross-talks with metabolism processes and physiological responses to biotic or abiotic stresses.It plays a key role in distributing carbohydrates and sugar signal transporting.In the present study,eight SnRK1 coding genes were identified in sorghum(Sorghum bicolor L.)via sequences alignment,with three forαsubunits(SnRK1α1 to SnRK1α3),three forβ(SnRK1β1 to SnRK1β3),and one for bothγ(SnRK1γ)andβγ(SnRK1βγ).These eight corresponding genes located on five chromosomes(Chr)of Chr1–3,Chr7,and Chr9 and presented collinearities to SnRK1s from maize and rice,exhibiting highly conserved domains within the same subunits from the three kinds of cereals.Expression results via qRT-PCR showed that different coding genes of SnRK1s in sorghum possessed similar expression patterns except for SnRK1α3 with a low expression level in grains and SnRK1β2 with a relatively high expression level in inflorescences.Results of subcellular localization in sorghum leaf protoplast showed that SnRK1α1/α2/α3/γmainly located on organelles,while the rest four of SnRK1β1/β2/β3/βγlocated on both membranes and some organelles.Besides,three combinations were discovered among eight SnRK1 subunits in sorghum through yeast two hybrid,includingα1-β2-βγ,α2-β3-γ,andα3-β3-γ.These results provide informative references for the following functional dissection of SnRK1 subunits in sorghum.展开更多
According to many years of experimental summary, regulations on planting technique of harmless feeding Sorghum bicolor (L.) Moenchwere studied from the application scope, basic demands of planting, preparation be fo...According to many years of experimental summary, regulations on planting technique of harmless feeding Sorghum bicolor (L.) Moenchwere studied from the application scope, basic demands of planting, preparation be fore seeding, demands of seeding, field management, clipping and harvesting, transportation, storage, ledger management and other technical requirements, and specific measures and technical indicators of the technical regulations were analyzed, so as to provide normalized, standardized, industrial and marketization technical support for the planting of harmless feeding S. bicolor (L.) Moench.展开更多
Sorghum metabolism continually adapts to environmental temperature as thermal patterns modulate diurnally and seasonally. The degree of adaptation to any given temperature may be difficult to determine from phenotypic...Sorghum metabolism continually adapts to environmental temperature as thermal patterns modulate diurnally and seasonally. The degree of adaptation to any given temperature may be difficult to determine from phenotypic responses of the plants. The present study was designed to see if the efficiency of quantum yield of photosystem II could be used as a measure of how well leaf tissue metabolism was able to withstand a prolonged respiratory demand caused by elevated temperatures. The efficiency of quantum yield values of Pioneer 84G62 and Northrup King KS585 commercial sorghum hybrids showed that when the hybrids were grown in a 28°C/20°C day/night cycle in the greenhouse or the field, Pioneer hybrid 84G62 withstood subsequent elevated thermal challenges better than Northrup King KS585. The same hybrids grown in a 39°C/32°C day/night cycle showed similar efficiency of quantum yield values when thermally challenged. Water-deficit stress increased the heat resistance of the tissue raising the efficiency of quantum yield of both lines to the same level. Upon recovery from the water deficit stress the differential efficiency of quantum yield values between the two lines re-appeared. The data provided in this study suggest a metabolic advantage of Pioneer 84G62 to environmental thermal challenges compared with the Northrup King KS585.展开更多
Sugar transporters are essential for osmotic process regulation,various signaling pathways and plant growth and development.Currently,few studies are available on the function of sugar transporters in sorghum(Sorghum ...Sugar transporters are essential for osmotic process regulation,various signaling pathways and plant growth and development.Currently,few studies are available on the function of sugar transporters in sorghum(Sorghum bicolor L.).In this study,we performed a genome-wide survey of sugar transporters in sorghum.In total,98 sorghum sugar transporters(SSTs)were identified via BLASTP.These SSTs were classified into three families based on the phylogenetic and conserved domain analysis,including six sucrose transporters(SUTs),23 sugars will eventually be exported transporters(SWEETs),and 69 monosaccharide transporters(MSTs).The sorghum MSTs were further divided into seven subfamilies,including 24 STPs,23 PLTs,two VGTs,four INTs,three p Glc T/SBG1 s,five TMTs,and eight ERDs.Chromosomal localization of the SST genes showed that they were randomly distributed on 10 chromosomes,and substantial clustering was evident on the specific chromosomes.Twenty-seven SST genes from the families of SWEET,ERD,STP,and PLT were found to cluster in eight tandem repeat event regions.In total,22 SSTs comprising 11 paralogous pairs and accounting for 22.4%of all the genes were located on the duplicated blocks.The different subfamilies of SST proteins possessed the same conserved domain,but there were some differences in features of the motif and transmembrane helices(TMH).The publicly-accessible RNA-sequencing data and real-time PCR revealed that the SST genes exhibited distinctive tissue specific patterns.Functional studies showed that seven SSTs were mainly located on the cell membrane and membrane organelles,and 14 of the SSTs could transport different types of monosaccharides in yeast.These findings will help us to further elucidate their roles in the sorghum sugar transport and sugar signaling pathways.展开更多
In Kansas, productivity of grain sorghum [Sorghum bicolor (L.) Moench] is affected by weather conditions at planting and during pollination. Planting date management and selection of hybrid maturity group can help to ...In Kansas, productivity of grain sorghum [Sorghum bicolor (L.) Moench] is affected by weather conditions at planting and during pollination. Planting date management and selection of hybrid maturity group can help to avoid severe environmental stresses during these sensitive stages. The hypothesis of the study was that late May planting improves grain sorghum yield and yield components compared with late June planting. The objectives of this research were to investigate the influence of planting dates yield and yield components of different grain sorghum hybrids, and to determine the optimal planting date and hybrid combination for maximum biomass and grains production. Three sorghum hybrids (early, medium, and late maturing) were planted in late May and late June without irrigation in Kansas at Manhattan/Ashland Bottom Research Station, and Hutchinson in 2010;and at Manhattan/North Farm and Hutchinson in 2011. Data on dry matter production, yield and yield components were collected. Grain yield and yield components were influenced by planting date depending on environmental conditions. At Manhattan (2010), greater grain yield, number of heads per plant, were obtained with late-June planting compared with late May planting, while at Hutchinson (2010) greater yield was obtained with late May planting for all hybrids. The yield component most affected at Hutchinson was the number of kernels∙panicle<sup>−1</sup> and plant density. Late-May planting was favorable for late maturing hybrid (P84G62) in all locations. However, the yield of early maturing hybrid (DKS 28-05) and medium maturing hybrid (DKS 37-07) was less affected by delayed planting. The effects of planting dates on yield and yield components of grain sorghum hybrids were found to be variable among hybrid maturity groups and locations.展开更多
The Primacy question addressed in our study is: Is the difterntial expression of rbcL gene in mesophyll cells and in bundle sheath cells related to the sequence of the gene per se?An enzymatic approach was fist establ...The Primacy question addressed in our study is: Is the difterntial expression of rbcL gene in mesophyll cells and in bundle sheath cells related to the sequence of the gene per se?An enzymatic approach was fist established to separate the two groups of cells. Microscopic examination revealed satisfactory separation effect: minimal mutual contamination was found so that no mistake might be introduced into biochemical or molecular biological expeitments using such preparations. CpDNA were isolated from mesophyll cells and from bundle sheath cells and coding region of rbcL gene was obtained from each by PCR ampilfication.Cloning and sequencing were then done on them.Compartive analysis , however, revealed identical sequence, with a length of 1,368 bp, encoding 456 amino acids. Since sequences of the non-coding regions of rbcL gene in masephyll sad bundle sheath have not been obtained, it can not yet be concluded that the differential expression is not related to the sequence itself. Nevertheless,It sesems justifiable to infer that whatever difference there may be between the sequences of rbcL gene in two groups of cells can only be found in the non-coding regions(including promoter and the 3' down stream region).展开更多
目的:采用液相色谱法同时测定二色补血草花中芦丁和槲皮素的含量。方法:Hypersil ODS2色谱柱(4.6 mm×250mm,5 μm),柱温为室温(约24℃),以甲醇和0.5%磷酸为流动相,梯度洗脱(甲醇:0 min为33%,20 min 为33%,25 min 为38%,60 min 为38...目的:采用液相色谱法同时测定二色补血草花中芦丁和槲皮素的含量。方法:Hypersil ODS2色谱柱(4.6 mm×250mm,5 μm),柱温为室温(约24℃),以甲醇和0.5%磷酸为流动相,梯度洗脱(甲醇:0 min为33%,20 min 为33%,25 min 为38%,60 min 为38%),流速1 mL·min^(-1),检测波长为355 nm。结果:芦丁在0.12~1.20 μg(r=0.9999)、槲皮素在0.04~0.40 μg(r=0.9997)范围内呈良好的线性关系;芦丁回收率为101.3%,RSD 为0.7%,槲皮素回收率为102.0%,RSD 为1.7%;样品溶液在15 h 内稳定。结论:该方法快速简单,线性关系良好。展开更多
基金Supported by National High-Technology Research and Development Program(863)(2007AA091701)~~
文摘[Objective] This study aimed to investigate the effects of different salt concentrations on the root vitality of Limonium bicolor (Bunge) Kuntze. [Method] Limonium bicolor (Bunge) Kuntze was treated with 0, 100, 200 and 400 mmol/L NaCl, respectively. After two weeks, root vitality, biomass and other physiological indicators were measured. [Result] Salt stress had significant influences on the growth of roots. Root vitality of Limonium bicolor increased firstly and reduced gradually with the increase of salt concentration. [Conclusion] The results indicate that Limonium bicolor has certain salt tolerance ability at low salt concentrations; under relatively high salt concentrations, Limonium bicolor roots can maintain high vitality; however, with the continuous increase of salt concentration, Limonium bicolor roots are damaged, with decreasing vitality.
基金supported by the National Natural Science Foundation of China(32001607)the Fundamental Research Funds for the Central Universities of Southwest University,China(SWU118087)。
文摘Sucrose nonfermenting-related protein kinase 1(SnRK1)is one of the critical serine/threonine protein kinases.It commonly mediates plant growth and development,cross-talks with metabolism processes and physiological responses to biotic or abiotic stresses.It plays a key role in distributing carbohydrates and sugar signal transporting.In the present study,eight SnRK1 coding genes were identified in sorghum(Sorghum bicolor L.)via sequences alignment,with three forαsubunits(SnRK1α1 to SnRK1α3),three forβ(SnRK1β1 to SnRK1β3),and one for bothγ(SnRK1γ)andβγ(SnRK1βγ).These eight corresponding genes located on five chromosomes(Chr)of Chr1–3,Chr7,and Chr9 and presented collinearities to SnRK1s from maize and rice,exhibiting highly conserved domains within the same subunits from the three kinds of cereals.Expression results via qRT-PCR showed that different coding genes of SnRK1s in sorghum possessed similar expression patterns except for SnRK1α3 with a low expression level in grains and SnRK1β2 with a relatively high expression level in inflorescences.Results of subcellular localization in sorghum leaf protoplast showed that SnRK1α1/α2/α3/γmainly located on organelles,while the rest four of SnRK1β1/β2/β3/βγlocated on both membranes and some organelles.Besides,three combinations were discovered among eight SnRK1 subunits in sorghum through yeast two hybrid,includingα1-β2-βγ,α2-β3-γ,andα3-β3-γ.These results provide informative references for the following functional dissection of SnRK1 subunits in sorghum.
基金Supported by Special Fund for Agro-scientific Research in the Public Interest(20120304201)~~
文摘According to many years of experimental summary, regulations on planting technique of harmless feeding Sorghum bicolor (L.) Moenchwere studied from the application scope, basic demands of planting, preparation be fore seeding, demands of seeding, field management, clipping and harvesting, transportation, storage, ledger management and other technical requirements, and specific measures and technical indicators of the technical regulations were analyzed, so as to provide normalized, standardized, industrial and marketization technical support for the planting of harmless feeding S. bicolor (L.) Moench.
文摘Sorghum metabolism continually adapts to environmental temperature as thermal patterns modulate diurnally and seasonally. The degree of adaptation to any given temperature may be difficult to determine from phenotypic responses of the plants. The present study was designed to see if the efficiency of quantum yield of photosystem II could be used as a measure of how well leaf tissue metabolism was able to withstand a prolonged respiratory demand caused by elevated temperatures. The efficiency of quantum yield values of Pioneer 84G62 and Northrup King KS585 commercial sorghum hybrids showed that when the hybrids were grown in a 28°C/20°C day/night cycle in the greenhouse or the field, Pioneer hybrid 84G62 withstood subsequent elevated thermal challenges better than Northrup King KS585. The same hybrids grown in a 39°C/32°C day/night cycle showed similar efficiency of quantum yield values when thermally challenged. Water-deficit stress increased the heat resistance of the tissue raising the efficiency of quantum yield of both lines to the same level. Upon recovery from the water deficit stress the differential efficiency of quantum yield values between the two lines re-appeared. The data provided in this study suggest a metabolic advantage of Pioneer 84G62 to environmental thermal challenges compared with the Northrup King KS585.
基金supported by the National Natural Science Foundation of China(32001607)the Fundamental Research Funds for the Central Universities of Southwest University,China(SWU118087)。
文摘Sugar transporters are essential for osmotic process regulation,various signaling pathways and plant growth and development.Currently,few studies are available on the function of sugar transporters in sorghum(Sorghum bicolor L.).In this study,we performed a genome-wide survey of sugar transporters in sorghum.In total,98 sorghum sugar transporters(SSTs)were identified via BLASTP.These SSTs were classified into three families based on the phylogenetic and conserved domain analysis,including six sucrose transporters(SUTs),23 sugars will eventually be exported transporters(SWEETs),and 69 monosaccharide transporters(MSTs).The sorghum MSTs were further divided into seven subfamilies,including 24 STPs,23 PLTs,two VGTs,four INTs,three p Glc T/SBG1 s,five TMTs,and eight ERDs.Chromosomal localization of the SST genes showed that they were randomly distributed on 10 chromosomes,and substantial clustering was evident on the specific chromosomes.Twenty-seven SST genes from the families of SWEET,ERD,STP,and PLT were found to cluster in eight tandem repeat event regions.In total,22 SSTs comprising 11 paralogous pairs and accounting for 22.4%of all the genes were located on the duplicated blocks.The different subfamilies of SST proteins possessed the same conserved domain,but there were some differences in features of the motif and transmembrane helices(TMH).The publicly-accessible RNA-sequencing data and real-time PCR revealed that the SST genes exhibited distinctive tissue specific patterns.Functional studies showed that seven SSTs were mainly located on the cell membrane and membrane organelles,and 14 of the SSTs could transport different types of monosaccharides in yeast.These findings will help us to further elucidate their roles in the sorghum sugar transport and sugar signaling pathways.
文摘In Kansas, productivity of grain sorghum [Sorghum bicolor (L.) Moench] is affected by weather conditions at planting and during pollination. Planting date management and selection of hybrid maturity group can help to avoid severe environmental stresses during these sensitive stages. The hypothesis of the study was that late May planting improves grain sorghum yield and yield components compared with late June planting. The objectives of this research were to investigate the influence of planting dates yield and yield components of different grain sorghum hybrids, and to determine the optimal planting date and hybrid combination for maximum biomass and grains production. Three sorghum hybrids (early, medium, and late maturing) were planted in late May and late June without irrigation in Kansas at Manhattan/Ashland Bottom Research Station, and Hutchinson in 2010;and at Manhattan/North Farm and Hutchinson in 2011. Data on dry matter production, yield and yield components were collected. Grain yield and yield components were influenced by planting date depending on environmental conditions. At Manhattan (2010), greater grain yield, number of heads per plant, were obtained with late-June planting compared with late May planting, while at Hutchinson (2010) greater yield was obtained with late May planting for all hybrids. The yield component most affected at Hutchinson was the number of kernels∙panicle<sup>−1</sup> and plant density. Late-May planting was favorable for late maturing hybrid (P84G62) in all locations. However, the yield of early maturing hybrid (DKS 28-05) and medium maturing hybrid (DKS 37-07) was less affected by delayed planting. The effects of planting dates on yield and yield components of grain sorghum hybrids were found to be variable among hybrid maturity groups and locations.
文摘The Primacy question addressed in our study is: Is the difterntial expression of rbcL gene in mesophyll cells and in bundle sheath cells related to the sequence of the gene per se?An enzymatic approach was fist established to separate the two groups of cells. Microscopic examination revealed satisfactory separation effect: minimal mutual contamination was found so that no mistake might be introduced into biochemical or molecular biological expeitments using such preparations. CpDNA were isolated from mesophyll cells and from bundle sheath cells and coding region of rbcL gene was obtained from each by PCR ampilfication.Cloning and sequencing were then done on them.Compartive analysis , however, revealed identical sequence, with a length of 1,368 bp, encoding 456 amino acids. Since sequences of the non-coding regions of rbcL gene in masephyll sad bundle sheath have not been obtained, it can not yet be concluded that the differential expression is not related to the sequence itself. Nevertheless,It sesems justifiable to infer that whatever difference there may be between the sequences of rbcL gene in two groups of cells can only be found in the non-coding regions(including promoter and the 3' down stream region).
文摘目的:采用液相色谱法同时测定二色补血草花中芦丁和槲皮素的含量。方法:Hypersil ODS2色谱柱(4.6 mm×250mm,5 μm),柱温为室温(约24℃),以甲醇和0.5%磷酸为流动相,梯度洗脱(甲醇:0 min为33%,20 min 为33%,25 min 为38%,60 min 为38%),流速1 mL·min^(-1),检测波长为355 nm。结果:芦丁在0.12~1.20 μg(r=0.9999)、槲皮素在0.04~0.40 μg(r=0.9997)范围内呈良好的线性关系;芦丁回收率为101.3%,RSD 为0.7%,槲皮素回收率为102.0%,RSD 为1.7%;样品溶液在15 h 内稳定。结论:该方法快速简单,线性关系良好。
