Background

Cotton(G.hirsutum L.)is an important natural fiber,which is estimated to generate over 3.4 billion kilograms of lint annually thereby supporting in excess of US$25 billion in products and services in the United States alone(USDA-ERS 2016).Cotton is valued primarily due to its use as a natural fiber product.Fiber quality is vital for creating high valued products and reducing waste during yarn processing and production in textile mills.With world-wideunpredictable rainfalleventsand declining levels of available ground water to use for irrigation,breeding programs around the world are engaged in developing cotton cultivars/germplasm with drought tolerance,superior yield and fiber quality.Producing rainfed cotton with high fiber quality has traditionally been difficult in the Texas High Plains because of unpredictable rainfall events or extended periods of drought during sensitive production developmental stages.Studies on the impact of irrigation on yield and fiber quality remains inconsistent and the true mechanisms by which fiber development is impacted by drought is not fully understood.Under different irrigation regimes fiber quality’s responses are sometimes different from what the conventional wisdom suggests(Bauer et al.2009;Ritchie et al.2009;Snowden et al.2013).The improvement of fiber quality traits such as length,uniformity,strength,elongation,maturity,and fineness,when under water stress or limited irrigation,may be even more complicated than improvement of these complex traits under well-watered conditions(Paterson et al.2003).

High yielding cotton with superior fiber quality is often grown where water is the limiting factor(Cook and El-Zik 1993).Reduced irrigation has been shown to have a negative impact on the quality of fiber(Pettigrew 2004;Snowden et al.2013;Feng et al.2014).However,this impact may be lessened through the identification of more drought tolerant genotypes.Identifying these genotypes may be difficult,because many researchers have suggested that only a small amount of genetic diversity exists in cultivated cotton species(Meredith Jr.2000;Ulloa et al.2009;Ulloa 2014;Hinze et al.2016).

One breeding method that has been used in the improvement of fiber quality involves the use of a mutagen such as Ethyl MethaneSulfonate(EMS)(Auld et al.2007;Brown et al.2012;Patel et al.2014).Previous studies reported that creating genetic diversity with EMS may improve fiber quality under well water conditions or non-stressed environments.

（1）人民币汇率预期与货物贸易跨境资金流出之间的脉冲响应分析。对人民币汇率预期、境内外利差与货物贸易跨境资金流出之间建立VAR模型，根据AIC准则确定检验滞后阶数为6阶，构建VAR模型后得出脉冲响应函数图（如图1所示）。

The objective of this study was to measure the impact of limited irrigation conditions on the fiber quality traits of EMS treated cotton populations and to further investigate the possibility to identify superior mutant lines with improved yield and fiber quality traits for public germplasm release.The following sub-objectives were also investigated in this study:a)to determine the effect of multiple irrigation rates and seasons on the fiber quality of EMS treated populations,and b)to identify potential EMS treated novel germplasm with improved fiber quality produced under diverse irrigation regimes.

Results

In 2014,because too many of the single plant inferior(referring herein as a poor yield and seed performer)selections did not produce enough fiber(10 g)to be tested by the High-Volume Instrument(HVI),the effect of the different irrigation regimes on the EMS treated populations was evaluated in only the superior(referring herein as an excellent/good yield and seed performer)selections.Ten grams is needed for the proper evaluation of fiber quality traits using the Uster 1000.Evaluation of seed cotton and lint yield data for this study has previously been published(Witt et al.2018).When the fiber traits(length,strength,micronaire,elongation,and uniformity)were evaluated,the Raider 276 and TTU 774 populations had no significant differences between the different irrigation levels(232mm and 347 mm)for all traits.However,significant differences(P≤0.05)were observed within the strength measurement of the Tamcot Sphinx population.Fiber strength ranged from 304 kilonewton meter per kilograms(kN·m·kg-1)for the high irrigation rate to 295 kN·m·kg-1for the low irrigation rate(Table 1).

Before 2015 planting season,independently of the fiber quality traits,a decision was made to further evaluate as many selections as possible from the low irrigation rate(232 mm)from the 2014 divergent selections,and if the seed was unavailable from the low rate to supplement with selections from the high irrigation rate(347mm).This decision was also based on the assumption that superior selections under low irrigation already experienced one cycle of drought selection.A total of 146 selections(46 from Raider 276,50 from TTU 774,and 50 from Tamcot Sphinx)were evaluated under three irrigation rates,within each irrigation rate.

In 2015,seeds from three original non-treated EMS(original seed source),two commercial controls Fiber-Max(FM)958 and Phytogen 72,and the fifth generation(M5)seeds from 146 selections(46 Raider 276,50 Tamcot Sphinx,and 50 TTU 774)representing the three selected populations from 2014 were sown at Location 1 in progeny rows.In 2015,based on yield potential and the previous year’s fiber quality data,33 of the 146 line-performers were advanced for further evaluation in the 2016 growing season as line-performers.Reselection was performed for superior morphological and agronomic traits.In 2016,the sixth generation(M6)seeds from the 33 reselections from 2015 and the same five controls were evaluated at Location 1 and Location 2[Texas Tech University New Deal Research Farm,New Deal,TX(33°43’N,101°44’W)].In 2014,the fiber quality traits were evaluated from the total harvested lint of single plants.In 2015,35 random bolls were harvested from plants within each plot to analyze the fiber quality by HVI at the FBRI.This was done to standardize the amount of fiber evaluated.At the end of the 2016 season,one meter of each plot was harvested to more accurately predict the fiber quality of each plot.Again,this fiber was evaluated by HVI at the FBRI.For consistency in naming,the 2014 selection criteria were used to name the genotypes in the subsequent years.

At the end of the 2015 growing season,a reselection for superior yield on either inferior or superior selections was executed based on visual boll-load(open bolls per plants in a research plot)over all three irrigation rates.First a progeny row was evaluated in the no irrigation rate(0 mm);then the line was confirmed if it also had a superior boll-load in the high(142 mm)and medium(71mm)irrigation rates.This reselection was performed to obtain the best possible lines with yield potential for replicated trials under different irrigation regimes and test sites in 2016,and with potential for a public germplasm release.Below are the 2015 results and comparisons(Tables2,3 and 4)from 33 EMStreated re-selections of three populations from the different trait analyses.These 33-selections were also planted for the 2016 season.

Para-lingual context also constrains the way of expressing ourselves.We Chinese have a saying:“见人说人话，见鬼说鬼话”,which means what you say should fit the on-spot context.Chen Zhi’an and Wen Xu(1997:24)give us a good example.The following sentences are both used to ask about the time.

一向温和镇定的朋友，在我面前刷刷地流下泪来——她和家人都没有料到，父亲是得了老年痴呆症。他的各种不可理喻的行为，包括把袜子塞进冰箱里，把擦脸油放进微波炉；忘了在烧水壶里加水就插上电干烧；不肯洗澡，拒绝理发，去了超市在外面转悠几小时找不到回家的路……在诊断结果出来后都有了解释。

In 2015,for the Raider 276 population under the high irrigation rate,there were significant differences(P≤0.05)for all fiber traits evaluated(Table 2).The fiber length ranged from 29.8mm for T13 to 27.6mm for T2.The elongation was highest for T35 at 10.4%and lowest for T18 at 6.6%(data not shown).In the medium irrigation rate,there were no significant differences for all fiber traits evaluated(Table 2).In the no irrigation rate,there were significant differences(P≤0.05)for the strength and elongation only(Table 2).The length ranged from 30.1 mm for T25 to 29.7mm for T41.The elongation ranged from 10.2%for T35 to 6.6%for T13 and T18.Fiber strength and elongation,followed by fiber length were impacted in the high and no irrigation rates,indicating more variability on the response of these traits to water stress.

In 2015,for the TTU 774 population under the high irrigation rate there were significant differences(P≤0.05)for micronaire,length,and strength.The length ranged from 30.7 mm for T82 to 27.1 mm for T65(Table 3).In the medium irrigation rate,there were significant differences for the length and strength.The fiber length ranged from 31.1 mm for T72 to 27.8 mm for T50(Table 3).In the no irrigation rate,there were significant differences(P≤0.05)for the strength and elongation.The fiber length was highest for T72 at 31.1 mm and lowest for T50 at 27.8 mm.The elongation ranged from 9.1%for T58 to 6.9%for T91 and T18.In all the irrigation rates,TTU 774 EMS treated selections’fiber traits responded to changes in water rates.

In 2015,for the Tamcot Sphinx EMS treated population under the high irrigation rate there were significant differences(P≤0.05)for all traits except the uniformity.The fiber length ranged from 31.4 mm for T163 to 27.9 mm for T179(Table 4).The elongation ranged from 9.1%for T164 to 7.2%for T177 and T188.In the medium irrigation rate,there were no significant differences for any of the fiber quality traits evaluated(Table 4).In the no irrigation rate,there were no significant differences(P≤0.05)for any of the fiber quality traits evaluated(Table 4).The length ranged from 27.4 mm for T180 to 25.4 mm for T188.The elongation ranged from 8.5%for T153 and T164 to 7.0%for T151 and T188.In 2015,for the Tamcot Sphinx selections variability in response to irrigation was only observed in the high irrigation rate.

最终监测结果如图17所示。可以看出，切眼左帮总位移约62mm，位移速率随着切眼扩帮的进行逐渐减小；切眼右帮在扩帮前位移量为零，随着扩帮的进行，位移量逐渐增大，总位移量约54mm，低于左帮位移量；切眼顶板总位移量约14mm，总位移量较小；切眼底板最终底鼓量约14mm。由以上数据可以看出，切眼左帮、右帮、顶板、底板变形量均较小，在允许的范围之内，且在整个工作面推进期间，均没有发生明显的破坏，支护效果良好。

In 2016,the 33 EMS treated re-selections from the three EMS treated populations were evaluated at two geographic locations and two irrigation rates(Tables 5 and 6)to assess the overall selection scheme in this study and to obtain the best possible selections with superior yield potential and fiber quality for a public germplasm release.The EMS treated selections were compared with the non-treated EMS controls,and to FiberMax(FM)958 and Phytogen 72 commercial cultivar checks.There were significant(P≤ 0.05)genotype by location and genotype by irrigation interactions,so the selections at the high irrigation rate at Location 1(Lubbock,TX)was evaluated separately from Location 2(New Deal,TX)to better understand genotypic differences.

When the EMS treated selections were examined in the high irrigation rate(106mm)at Location 1,significant differences(P≤0.05)were observed in micronaire,uniformity,and elongation between the Raider 276 line-performersand the originalnon-treated EMS source(data not shown).The fiber length ranged from 29.9 mm for T18 to 26.8mm for T35(Table 5).The elongation ranged from 10.2%for T35 to 5.4%for T46.In the no irrigation rate(0 mm)of Location 1,significant differences(P≤ 0.05)were observed in micronaire,length,uniformity,and elongation between the Raider 276 selections and the original non-treated EMS source(data not shown).The fiber length was highest for T38 at 28.8 mm and lowest for T2 at 26.2 mm(Table 5).For the TTU 774 selections in the high irrigation rate at Location 1,there were significant differences for all the traits evaluated.The fiber length ranged from 31.2mm for T72 to 27.3 mm for T50(Table 5).For the TTU 774 selections in the no irrigation rate at Location 1,there were significant differences for all the traits evaluated.T72 had the highest fiber length(29.4 mm)and T58 had the lowest(25.9 mm).T58 had the highest elongation(9.6%)and T55 had the lowest(6.5%).For the Tamcot Sphinx line-performers in the high irrigation rate(106 mm)at Location 1,there were significant differences(P≤0.05)for all the traits evaluated(data not shown).The fiber length ranged from 28.8 mm for T152 to 24.5 mm for T150(Table 5).For the Tamcot Sphinx selections in the no irrigation rate(0 mm)at Location 1 there were significant differences for all the traits evaluated exceptuniformity (data notshown).The originalnon-treated EMS source had the highest fiber length(27.9 mm)and T179 had the lowest(23.8mm)(Table 5).T164 and T188 had the highest elongation(10.1%)and T169 had the lowest(7.2%).

In 2016,in the high irrigation rate(106 mm)of Location 2,there were significant differences(P≤0.05)in micronaire,length,and elongation between Raider 276 selections and the original non-treated EMS source(data not shown).The fiber length ranged from 31.9 mm for T10 and the original non-treated EMS source to 29.1 mm for T2(Table 6).In the no irrigation rate(0 mm)of Location 2,there were significant differences in micronaire and strength.The fiber length was highest for T10 at 29.0 mm and lowest for T35 at 27.0 mm(Table 6).For the TTU 774 selections in the high irrigation rate at Location 2,there were significant differences(P≤0.05)for all the traits evaluated.The fiber length ranged from 32.8 mm for T72 to 29.2mm for T91(Table 6).For the TTU 774 selections in the no irrigation rate(0mm)at Location 2,there were significant differences(P≤0.05)for all the traits evaluated except for fiber uniformity(data not shown).T72 had the highest fiber length(30.9 mm)and T50 had the lowest(26.8 mm)(Table 6).T58 had the highest elongation(9.0%)and T91 had the lowest(6.4%).For the Tamcot Sphinx selections in the high irrigation rate at Location 2,there were significant differences(P≤0.05)for all the traits evaluated.The fiber length ranged from 31.5 mm for T152 to 26.8 mm for T179(Table 6).For the Tamcot Sphinx selections in the no irrigation rate(0 mm)at Location 2,there were significant differences(P≤0.05)for all the traits evaluated.T152 had the highest fiber length(28.0 mm)and T150 had the lowest(23.1mm)(Table 6).T188 had the highest elongation(11.0%)and T151 had the lowest(7.7%).

3）现代职业教育制度的扩大实验。2010年，江苏省印发《职业教育创新发展实验区建设方案》，提出“推动建立现代职业教育制度，增强职业教育吸引力和发展能力。”2012年，贵州省出台九大举措，大力发展职业教育，其中一项是“探索建立完善现代职业教育制度”，在体系建设上，要求从学历层次上完善职业教育体系建设，职业教育不再局限在中高职层次，而要打通从中等职业教育、高等职业教育、本科职业教育的立交桥政策；同时深化考试和招生改革，在专业、学校、层次等几个方面扩大对口升学、对口招生的规模，从而从根本上增强职业教育的吸引力。

No other data related to this study is available at this time.

1.3.1 气温 从图2可以看出，近 37年来，南丰县年平均气温、年平均最高气温、年平均最低气温随着全球气候变暖而升高。年平均气温最高出现在2017年，达19.5℃；年平均气温最低出现在1984年，为17.4℃；年平均气温最高年的2017和年平均气温最低的1984年相差2.1℃。

In 2016,for the Raider 276 selections,in all irrigation rates and at both locations,the fiber length,strength and elongation had an increase in the number of unique classes for mean separation.In the TTU 774 selections,variability in mean separation was increased for the length and uniformity when compared with the original non-treated EMS source in all irrigation rates and at both locations.In the Tamcot Sphinx population,increased variability in mean separation was seen for all traits when compared with the original non-treated EMS source.Each population had several lines with increased yield and fiber quality when compared with the original non-treated EMS source.However,most selections were only improved in a few traits when compared with the original non-treated EMS source.The diverse responses of yield and fiber quality suggest that EMS treated populations could be used as a genetic source in a breeding program to increase fiber quality or as future germplasm releases.

Discussion

In this study,the novel genetic variability created by the chemical mutagen Ethyl MethaneSulfonate(EMS)was evaluated to determine the impact of limited irrigation conditions on the fiber quality traits of EMS treated cotton populations and successive selection-procedures,and to further investigate the possibility to identify superior genotypes with improved yield and fiber quality traits under diverse irrigation regimes for public germplasm release.Producing rainfed cotton with high fiber quality has traditionally been difficult in the Texas High Plains because of unpredictable rainfall events or extended periods of drought during sensitive production/developmental stages.Fiber traits such as micronaire,length,strength and elongation,and seed cotton yield tended to be more impacted by irrigation regime.On average,the fiber length and at some level,fiber strength selections were the most negatively impacted by reduced irrigation or the lowest rates from all populations.Selections were identified with significantly(P≤0.05)better fiberquality traitsand similarlintyieldsto the commercial control.These lines could be useful for improving the fiber quality of cotton under limited irrigation conditions,benefiting the future cotton production of the Texas High Plains.

Different experimental designs were used each year to evaluate the different number of selections and seed availability;in 2014,a complete randomized block was used within each irrigation rate with the 25 similar selections used as replications to determine the effect of the divergent selection;in 2015,an augmented design(used for a small amount of seed,(Federer 1956))was used with controls(3 non-mutant checks and 2 commercial checks)and three blocks;and in 2016,a randomized complete block was used with three replications within each water-rate at each location.Due to the different experimental designs and selections made the 3 years had different statistical analysis.In 2014,the differences between superior line-performers and inferior line-performers for each population were determined using PROC GLIMMIX(Fisher’s protected LSD)to distinguish between means(SAS Institute,2013).In 2015,PROC MIXED with solutions(Dunnett’s test)was used for evaluating between mean differences(SAS Institute,2013).The solutions were determined by using the original non-treated EMS source and commercial controls evaluated as fixed effects and the test lines as random effects.In 2016,the differences between the selections and the original non-treated EMS source were determined using PROC GLIMMIX(Fisher’s protected LSD)used to distinguish between the means(SAS Institute,2013).

The selection method used in this study was able to capture a superior amount of variation when compared with the original non-treated EMS source for most traits and within most irrigation rates.However,the amount of variation seen differed from year to year.This may be due to several factors.The first is that the inferior/poor selections were not evaluated in 2014,because they produced too little fiber for the HVI to measure.The elimination of these selections from our study reduced the amount of observed diversity in our analyses.The second is that the plants were selected primarily on diversity in yield potential and not on fiber quality.Yield and fiber quality have been shown to be negatively correlated(Miller and Rawlings 1967;Meredith Jr.and Bridge 1971;Culp and Harrell 1973).The third factor is that cotton fiber quality changes within a plant and from different growing environments(temperature,precipitation,etc.,...)(Kelly et al.2015).The fourth factor is that fiber quality in EMS treated populations has been shown to have a relatively low heritability(Herring et al.2004).This makes it difficult to separate the effect of the EMS and the effect of the irrigation when evaluating the responses to irrigation in this study.Despite these difficulties,the average value of some traits from the selections were able to be improved in all three EMS treated populations when compared with both the original non-treated EMS source and the commercial check-cultivars.

The authors would also like to thank Dr.Auld DL for providing the EMS treated populations used in this study and students working at Texas Tech University,PSS and USDA-ARS,Lubbock,TX for assisting in collecting data from these populations.Mention of trade names or commercial products in this article is solely for the purpose of providing specific information and does not imply recommendation or endorsement by the U.S.Department of Agriculture.The U.S.Department of Agriculture is an equal opportunity provider and employer.

In this study,there were differences in the performance of the selections from the different EMS treated populations.However,the general trend is that the strength of the Raider 276 population,the strength and elongation of the Tamcot Sphinx population,and the length and elongation of the TTU 774 population were all higher than their original non-treated EMS source.In addition,in non-stressed environments,micronaire,length,and strength were all improved through the use of EMS(Brown et al.2012).

Conclusion

This study provides support that EMS seems to have created genetic variability in most traits and most irrigation rates evaluated in this study.This EMS genetic variability is promising for using in a breeding program to improve the fiber quality of cotton.Water stress appears to have a negligible impact on fiber uniformity.However,other fiber traits especially fiber length and strength were impacted by the stress.The effect of EMS on different fiber traits from different populations leads to the necessity to study this further.Additional research is ongoing to examine and validate the contribution of the EMS treatment on selected line-performers by genotyping using single nucleotide polymorphisms(SNPs),that may positively or negatively contribute to the variability found in the fiber properties of these lines.In addition,even though,no significant differences for yield were observed between some selected line-performers and controls or commercial check,several line-performers showed superior fiber quality and superior yield.Some of these selections will be further evaluated as possible germplasm releases.This study increased our understanding of the variability that may be created by EMS in cotton populations and it increased our understanding of the stability of these traits across irrigation rates and locations.

Materials and methods

Plant material and data collection

Seed from the following genotypes ‘Raider 276’(Texas Tech University PI 645 568)(Auld et al.2007),‘Tamcot Sphinx’(El-Zik and Thaxton 1996)(Texas A&M University PI 592 801),and ‘TTU 774’(Texas Tech Univ.PI 643 915)(Bechere et al.2006)were treated with EMS and bulk harvested from the first to the third generation(M1-M3).These genotypes had been treated with EMS using a previously described method(Auld et al.1998).These genotypes were selected for treatment due to their adaptation to the Texas High Plains,including yield and fiber quality.In 2014,the fourth generation(M4)seeds from these populations were grown at Location 1[Texas Tech University Quaker Research Farm,Lubbock,TX(33°35’N,101°52’W)].At the end of the season,divergent selection based on morphologicaland agronomic traits was performed in each population to obtain a diverse panel of individuals with normal distribution of traits.Within each of these three selected populations,25 superior single plant selections and 25 inferior single plant selections were chosen within each irrigation rate(100 individuals per population)for evaluation in 2015 as progeny rows.All the bolls from each plant were hand harvested to obtain the seed-cotton from the selections.The seed cotton was ginned on 10-saw or 20-saw gin(Compass Systems Model TT510 or TT520,Carmel,IN).

The agronomic traits of seed-cotton yield,lint yield,and lint percent were calculated based on a per plant basis.The fiber was then evaluated by High-volume instrument(HVI)[Uster HVI 1000 using a 1-2-2 protocol for fiber quality measurements(micronaire,length,strength,uniformity,and elongation)]at the Fiber and Biopolymer Research Institute(FBRI),Lubbock,TX.Due to the minimum fiber volume requirements,to process plant samples with HVI(10 g of lint),42 of the lines could not be evaluated.In addition,154 selections were also discarded due to a lack of available seed for further evaluation.

Most of the fiber quality traits evaluated in 2015 from the EMS treated populations were not significantly different from the non-treated EMS or original non-treated EMS source for all three populations under all three irrigation rates.However,fiber uniformity and elongation were greater than or equal to the original non-treated EMS source in all three irrigation rates(data not shown).In the EMS treated populations of Raider 276 and Tamcot Sphinx,fiber strength was also greater than or equal to the original non-treated EMS source in all three irrigation rates.In the EMS treated populations and the controls there was no consistency or observed trend in the response of the fiber quality traits to the different irrigation regimes.However,it was clear that higher variability in response was observed under high irrigation than no irrigation in 2015.

Irrigation&soil type

Location 1 has an Acuff loam soil(Fine-loamy,mixed,superactive,thermic Aridic Paleustolls)and Location 2 has a Pullman clay(Fine,mixed,superactive,thermic Torrertic Paleustolls);irrigation was applied once a week using sub-surface drip irrigation with 30cm spacing between emitters placed approximately 25cm below the soilsurface.During thethree-yearstudy,different weekly irrigation regimes were applied to research plots,due to rainfall events to ensure differences in plant stress.Each year,two meters of buffer cotton(plots)were placed around each irrigation rate,to prevent one irrigation rate from effecting the plants within the other.In 2014,at Location 1 seeds were sown in single rows within two irrigation rates(232 and 347 mm annually)at a rate of ten seeds per meter for a total of 2290 individual plants, which were used for single plant line-selections(superior and inferior plant selections)from each irrigation rate.In 2015,at Location 1 selections from 2014 were grown within three irrigation rates(0,71,and 142 mm annually)in 4.5 m-plots.In 2016,at Location 1 and 2,selected progeny rows were evaluated in 4.5 m-plots with two irrigation rates(0 and 106 mm annually).

Data analysis

Traditionally,cotton is known to suffer from a limited amount of genetic diversity(Meredith Jr.2000;Hinze et al.2016).This lack of diversity is predominantly driven by the over use of the same parent or closely related parent material.For example,the Acala germplasm,known for its high quality fiber,had been used in 73%of the commercial cultivars released between 1970 and 1990(Bowman et al.1996).Many times this problem is amplified by the creation of a new cultivar from the reselection of an old or obsolete cultivar(Van Esbroeck and Bowman 1998).Mining the genetic variability from a gene pool or collection,or increasing the diversity of germplasm in a breeding program is one of the most important tasks for a plant breeder(Dudley and Moll 1969;Meredith Jr.1984;Ulloa 2006;Zeng et al.2017).This study was not designed to compare the amount of genetic variability created by EMS and other methods such as using parental crosses or hybridizations.However,some comparisons can be made by using observations from past studies evaluating EMS or parental crosses.When compared with the non-treated EMS original source or control,EMS appears to have created some type of variability affecting different fiber traits in different populations besides the effect or impact of irrigation.The fiber quality traits of length,strength,and elongation are believed to be controlled by complete or partial dominance(Verhalen and Murray 1965;Al-Rawi and Kohel 1970).A biparental cross can show very high heritability for fiber traits while a Design II mating can show lower heritability(May and Green 1994;Ulloa 2006).Genetic variability from a biparental cross depends on the general and specific combining abilities of the parents(Gardner and Eberhart 1966;Hinze et al.2011).To measure this variability,usually,the F1,F2,and parents are compared(May and Green 1994;Tang et al.1996;Ulloa et al.2010).Like a biparental cross,the most important part of creating variation through EMS is the starting source(parent)that will be treated with the mutagen.Currently,there is no method to measure the variability or genetic diversity created by using a chemical mutagen such as EMS in cotton.

Abbreviations

EMS: Ethyl methanesulfonate; FM: FiberMax; HVI: High-Volume Instrument;kN·m·kg- 1: Kilonewtons meter per kilogram; M1, M2, etc: The first mutated generation, the second mutated generation, etc; SNP: Single nucleotide polymorphism

Acknowledgements

In a four-year study,the fiber traits that were evaluated fluctuated in their significance(Pettigrew 2004).For example,the fiber strength ofthe irrigated and non-irrigated plots was significantly different for only two of the 4 years.In this study,some traits occasionally appeared to have better fiber quality in water limited conditions.For example,fiber strength in the EMS treated populations was highest in the medium irrigation rate in 2015.Some selections in some of the EMS treated populations tended to benefit by small deficits in irrigation,increasing the quality of the above fiber traits as shown in the 2015 medium-irrigation regime(some levels of stress)in this study.However,for the commercial checks this was not the case.Other studies also occasionally found better fiber quality in the lower irrigation rate than the high irrigation rate(Pettigrew 2004;Bradow and Davidonis 2010;Karademir et al.2011).One reason for the increase in fiber quality may be due to fewer bolls being produced and taking resources from the bolls already produced (Bradow and Davidonis 2010).Another reason is because only a minimum number of bolls have been retained;whereas in a higher irrigation rate bolls that do not have enough time to fully develop may still be produced,so fiber quality parameters are lowered(Bradow and Davidonis 2010).In water-stressed and non-stressed plants,the size of the bolls are not different,only the number(Krieg and Sung 1986).Overall,decreased irrigation had a negative impact on the fiber quality of the EMS treated selections,the original non-treated EMS sources,and the commercial checks.The exception to this observation is the medium irrigation rate that had the higher fiber quality than the high and no irrigation rates in 2015.This may indicate that some stresses at the right developmental fiber stage are required to produce cotton with high fiber quality on the Texas High Plains.However,additional research is needed to further evaluate the above statement with a diverse germplasm-set,multiple irrigation rates and multiple test environments to determine where this beneficial stress ends.

Funding

[6][7][14][17][84][85]Thakin Nu, From Peace to Stability, Ministry of Information, Government of the Union of Burma, 1951, p.22, 51, 21-22, 202, 102, 98-100.

This study was funded by the Ogallala Aquifer Program with a collaborative project between Texas Tech University and USDA-ARS,PA,Cropping System Research Laboratory,Lubbock,TX,and by USDA-ARS(Project 3096-21000-019-00-D)(MU).

Availability of data and materials

Although the different selections from the different populations had differing levels of diversity depending on the fiber trait evaluated and the location and environment,some of the populations produced selections with superior fiber quality when compared with the commercial check FM 958.Also,some of the selections had superior fiber quality when compared with the non-mutated or non-treated EMS control-parent.For the Raider 276 population,there was a diverse response of the genotypes to the different irrigation rates for the fiber micronaire,length,strength,and elongation when compared with the original non-treated EMS source.In the TTU 774 population,the fiber length and strengthshowed a variable response to irrigation when compared with the original non-treated EMS source in all irrigation rates.However,the micronaire had a similar response to the different irrigation regimes.In the Tamcot Sphinx population,the number of classes for mean separation for the length,uniformity,strength,and elongation were increased.

Authors'contributions

Witt TW and Ulloa M conceived and designed the research,Witt TW and Ulloa M performed the experiments and prepared the materials,Witt TW and Ulloa M analyzed the data,Witt TW wrote the paper,Ulloa M,Pelletier MG,Mendu V,and Ritchie GL revised the manuscript.All authors read and approved the final manuscript.

Ethics approval and consent to participate

Not applicable.

2.4饮食护理:低碘饮食,嘱咐患者多饮食白开水,多食用富含蛋白质、能量与维生素的食品,严禁服用生冷、辛辣与刺激性食品,并注意食物的消化性等。

Consent for publication

2家酒店表示虽然他们不排斥其他消费群体，但通过对社交媒体平台的设计，呈现出一种新风格和新趋势，以此来吸引那些求新求变的顾客群体。3家酒店表示他们更喜欢那种具有品牌忠诚度的消费者。3家酒店显示他们更关注年龄在24-35岁的女性顾客，所以在其社交媒体平台宣传中特别强调了酒店的水疗实施和健身实施。

Not applicable.

Competing interests

观察两组咳嗽、呼吸困难、肺部哮鸣音等消失时间、住院时间以及临床疗效。疗效判定分为显效：患儿临床症状、肺部体征显著改善或消失，PEF%大于80%；有效：患儿临床症状、肺部体征有所改善，PEF%在60%～79%；无效：未达到上述标准，甚至严重。总有效率＝（显效+有效）/总例数×100%。

The authors declare that they have no competing interests.

A

1uthor details Plant and Soil Sci2ence Department,Texas Tech University,Lubbock,TX

式(13)右边是标量乘积,左边则是矢量点乘,其中一个是末端距矢量,另一个是在z轴上链延伸的极小量,其点积可以看成是矢量在方向上的投影与的乘积,而在方向即z轴上的投影正好是投影长度的模为dL,因此该式成立.

79409-2122,USA.USDA-ARS,PA,CSRL,Plant Stress and Germplasm

与模糊综合评判相比，层次分析法从某种程度上忽略了人为的判断模糊性，当过多的不确定性因素以及模糊性的因素出现时，就会使得层次分析法受到相应的影响[3]。

Development Research,Lubbock,TX 79415,USA.3USDA-ARS Cotton

Production and Processing Research Laboratory,Lubbock,TX 79403,USA.

摘 要：当今社会，信息技术发展迅猛，并被广泛地应用于教育领域，促进了教学改革趋于信息化方向发展。因此，在新时期教学环境下，物理教师需要结合初中生物理学习需求，优化物理课堂教学，利用多媒体构建信息化物理课堂，为学生构建良好的物理学习体系。围绕多媒体和信息化教学在初中物理课程中的具体应用，展开有效分析，从而为实现物理教学的课堂改革，提供重要的依据。

Received:23 August 2018 Accepted:20 November 2018

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