Yuan Feng•Yanze Yu•Linqiang Zhong•Weiqi Zhang•Minghai Zhang

Introduction

For free-living ungulates,the quality of their food is a key factor impacting their behavior and performance.Suttie and Hamilton(1983)revealed that the plane of nutrition is the single most important factor determining body weight in red deer.Body weight of deer is an indictor of body growth and fecundity(Albou et al.1986;Galliard et al.1992).Body weight is one constraint on entry into puberty for young female red deer(Hamilton and Blaxter 1980;Asher and Cox 2013).Pre-mating nutritional status of female red deer may affect the sex ratio of the offspring(Luna-Estrada et al.2006).

During the long,harsh Arctic winter,caribou eat lichens that are low in crude protein(CP)in advance of the early spring birthing and lactation seasons,and this results in a negative protein balance that lasts for 7 months(Gerhart et al.1996).Lichens contain relatively high content of digestible energy and the ratio of digestible energy to CP in lichens is higher than that of other species forged by caribou during winter(Parker et al.2005).Caribou show strong seasonal variations in nutritional requirements and acquisition.High demand for digestible energy during winter and for lactation in summer are the most important nutritional factors limiting Alaska black tailed deer(Parker et al.1999).Similarly,white-tailed deer(Odocoileus virginianus)in Quebec,Canada,selected winter forage species that contained the highest content of digestible energy,re flecting the physiological demands of winter survival(Berteaux et al.1998).Energy intake of red deer hinds during lactation is a major determinant of calf growth performance(Asher et al.2011).The annual energy balance is usually more sensitive to changes in energy intake than energy expenditure;therefore,wild animals may not limit their maximum energy intake(Parker et al.2009).

Another important factor for evaluating the nutritional value of plants is Dry Matter Digestibility (DMD).McDonald etal.(1995)showed thatplants with DMD＞50%foraged by ruminants were considered to be high-quality food.DMD can be determined both by experiments and by theoretical calculations.Ouyang et al.(2000)compared the mask method with the ash insoluble acid(AIA)method for the determination of daily intake and drymatter digestion by Tibetan goats and reported similar results from the two methods.Lei(1994)used statistical analysis to investigate the relationship between DMD of alfalfa(Sativa medicago)and its chemical composition.They concluded that quantifying crude fiber content was the most reliable method for estimating the DMD of alfalfa.

The nutritional quality of plants,especially at northern latitudes,is generally much lower in winter than in other seasons(Gonzalez-Hernandez and Silva-Pando 1999;Lo´pez-Pe´rez et al.2012;Parlak et al.2011;Tixier et al.1997).The aim of this study was to evaluate nutritional components of winter diets of red deer(Cervus elaphus xanthopygus)occupying the Muling forest region of northeastern China.We investigated the energy content and macronutrients(crude protein,crude lipid,non- fiber carbohydrate(NFC),andneutraldetergent fiber(NDF))of15plant species foraged by red deer in January of two consecutive years.We quanti fied relationships between energy content and macronutrients and fiber content of the 15 plant species.

Materials and methods

The study area was the Muling Dongbei Hongdoushan Nature Reserve(MDHNR).This reserve is located in southeastern Heilongjiang Province.It has a typical temperate continental monsoon climate,four seasons,and an annual average temperature of-2°C.Winter in the reserve is cold and long,with an extremely low temperature in January(minimum-43.8°C).The snowfall period is from October to April with an average depth of 500 mm.Red deer forage plant samples were collected in January 2014 and 2015.Fresh trails of red deer in the reserve were followed and feces and plants along the trails were collected for laboratory analysis.CP content was determined by measuring total nitrogen concentration according to the Kjeldahl method.We used Soxhlet equipment with an ether-ethyl solvent to quantify crude lipid(CL)content.NDF,ADF(acid detergent fiber),and ADL(acid detergent lignin)were quanti fied using the Van Soest technique(van Soest and Lewis 1991).The relation between the content of various cellulose-base substances was calculated by the relative amount of NDF compounds,including the proportions of cellulose,hemicellulose and lignin in NDF.DMD was estimated by theoretical calculations based on ADF and nitrogen content as outlined by Oddy et al.(1978).The formula is given as follows:DMD=83.58-0.824ADF+2.626N%

To investigate the relationship between macronutrients and energy content,we used the Pearson product-moment correlation coefficient(PPMCC or PCC)calculated as follows:

PPMCC is a measure of the linear correlation between two variablesxandy.It has a value between+1 and-1,where 1 is total positive linear correlation,0 is no linear correlation,and-1 is total negative linear correlation.r is the coefficient of association and n is sample size(Gao et al.2011).

For representing the plant species foraged by red deer,we listed the abbreviations and icons which used in the figures and tables of this study(Table 1).

Results

Nutritional composition of red deer winter diets

The nutritional composition of 15 species foraged by red deer varied widely(Table 2).Energy content was statistically similar for all foraged plant species and averaged 18.4±0.7 kJ/g across all species.Among these,Taxus cuspidatehad the highest energy content(19.7 kJ/g),followed byEuonymus verrucosus(18.9 kJ/g)and the lowest energy content was recorded forPopulus cathayana(16.7 kJ/g).Carbohydrate,the most important component,accounted for 84.8±1.9%of total weight of dry matter,ranging from 82.2 to 88%of dry weight.CP accounted for 7.5±1.7%of dry matter weight,ranging from 4.5%to 10.3%and varying most widely among the 15 species.Higher CP content was recorded forAralia elata(10.3%),Euonymus alatus(9.5%),T.cuspidate(9.3%),andUlmus pumila(9.3%).In contrast,Acer ukurunduensecontained the lowest CP content(4.5%),followed byP.cathayana(4.8%).Crude lipid(CL)content was statistically similar for all plant species.Ten of the fifteen species had CL content ranging from 5 to 7%（x=7±1.5%）.The highest CL content was recorded forSaussurea manshurica(9.8%)andP.cathayana(9.7%),and the lowest content forU.pumila(5.4%),Acer tschonoskii(5.6%)andAcer tegmentosum(5.6%).NFC content averaged 20.1±4.8%and varied widely among the 15 species.S.manshuricaexhibited the highest NFC content(up to 28.8%)andFraxinus mandshurica,a tall tree,had the lowest(13.5%).The 15 species had relatively stable but low ash content,averaging 0.8±0.3%.Tilia amurensishad the lowest ash content(0.3%).The following species had ash content＞1%:Equisetum hyemale(1.2%),P.cathayana(1.1%),A.ukurunduense(1%),A.tschonoskii(1%),T.cuspidate(1%)andEuonymus macropterus(1%).DMD varied little by species(Table 2),averaging 46.1±4.8%.Thirteen of the fifteen species had DMD＞40%.E.verrucosus(38.7%)andA.ukurunduense(39.4%)had the lowest DMD levels,whileS.manshurica(54.6%),A.elata(53.2%),andE.hyemale(52.1%)had the highest DMD levels.

Table 1 Plants species foraged by red deer in the reserve and their respective abbreviations and icons

The relationship between macronutrients and energy content

Macronutrients of plants are carbohydrate,CP and CL.These three types of nutrients can be converted into energy to fuel life activities.There was no correlation between CP content and energy content(r=0.004)in red deer forage species(Fig.1a).There was a statistically insigni ficant negative correlation between CL content and energy content(r=-0.190;Fig.1b).Carbohydrate was composed of NFC and NDF.NDF,included cellulose,hemicellulose,and lignin.These are main components of the plant cell wall and can not be used by animals other than ruminants.NDF content and energy content were significantly and negatively correlated(r=-0.343;Fig.1c).NFC mainly includes sugar(monosaccharide and starch),pectin,and organic acids.These are critical as the main energy sources and they release energy directly.NFC content and energy content were strongly and positively correlated(r=0.451;Fig.1d).

The relationship between fibers in winter diets of red deer

Fiber content varied significantly among the 15 species of forage plants(Table 2).Average NDF was 64.7±5.9%.F.mandschuricahad the highest NDF content at 71.8%,followed byE.verrucosus(71.7%)andA.ukurunduense(70.4%).Species with NDF content＜60%were:S.manshurica(53.5%),E.hyemale(56.2%),T.cuspidate(57.5%),andA.elata(58%).Cellulose content averaged 35±4.9%.P.cathayanahad the highest cellulose content at 40.8%,followedbyA.elata(39.5%),andT.cuspidatehadthelowest at 20.5%.Mean hemicellulose content was 16.2±2.4%.F.mandshuricahad the highest hemicellulose content at 23.3%whileT.cuspidatehad the lowest at 11.9%.Twelve of fifteen species showed hemicellulose content ranging from 15 to 18%.Lignin contentranged from 1.6 to 25.1%（x=13.4±5.5%）and was lower than the content of celluloseorhemicelluloseacrossall15species.Thehighestvalues wererecordedforT.cuspidate,andthelowestforE.hyemale.Cellulose,hemicellulose,and lignin percentages accounted fortheNDFofthe15species(Fig.2).ThecellulosecontentofE.hyemaleaccounted for the highest proportion of NDF at＞70%.Cellulose content ofTaxus cuspidateaccounted for the lowest proportion of NDF at 35.6%.The cellulose contents of the remaining 13 species ranged from 45 to 60%of NDF.Hemicellulose content was similar for all 15 species,rangingfrom20to30%exceptforF.mandshurica,whichhad over 35%.Lignin content was highly variable,ranging from 2.9(E.hyemale)to 43.6%(T.cuspidata),with the remaining 13 species ranging from 10 to 30%.

Discussion

Nutritional composition of winter diets of red deer

?

CP content is commonly used as an index of dietary quality in ungulates(Chen et al.1997).Gao and Yang(2004)studied farmed red deer and concluded that 27.3%of the newborns were weak when CP content of the fodder for pregnant red deer was 8.5%.However,offspring were healthy when CP was raised to 9.8%(ibid.).Similar results were reported for white-tailed deer by Murphy and Coates(1966).Elahi and Rouzbehan(2008)concluded that a CP content of 7–8%was required to maintain rumen microbial activity.For female red deer,a daily intake of 7%CP content is required to meet physiological nitrogen demands(Mould and Robbins 1981).In our study,average CP content was 7.5%,lower than that estimated for winter foraged of wapiti(Cervus elaphus roosevelti)in primary forest of western Washington,USA(9.2%)(Leslie et al.1984),and half of the CP content of forage consumed by red deer in mixed broadleaf-conifer forest of western France(15%)(Verheyden-Tixier et al.2008).The main reasons for these differences in CP content was variation in climate and vegetation.In western France,grasses,whose CP content was higher than that of other plants,accounted for most of the red deer winter diet.The local warm climate was conducive to the growth of gramineous plants that provided an abundant and high-protein resource for wintering red deer(Verheyden-Tixier et al.2008).Due to the deep snow accumulation typicalofsoutheastern Heilongjiang,highprotein grasses were generally unavailable to wintering red deer on our study area and consequently the CP content of their winter forage was low.

Soluble sugar is an important component of NFC.Although some reports have concluded that herbivores prefer plants containing soluble sugars,CP is not a crucial nutritional component determining forage species selection of herbivores(Bugalho and Milne 2003;Verheyden-Tixier et al.2008;Laska 2001;Tixier et al.1997;Parsons et al.2006).Verheyden-Tixier et al.(2008)reported on the nutritional selection of red deer in the mixed broadleaf-conifer forest of western France.Deer here had adequate food resources and mainly ate gramineous plants,usually avoiding conifers and ferns due to their higher lignin content and risk of toxicity despite the fact that their soluble sugar content is high(ibid.).T.cuspidateis a rare and endangered Taxus species and the only conifer in the winter diets of the red deer in the Muling forest region.Taxinol,which is obtained fromTaxus cuspidate,can inhibit cancer cell division and is considered a promising anti-cancer drug.However,the taxines also derived fromTaxusplants can harm the respiratory system of animals,and in severe cases,can cause respiratory failure and death(Shanker et al.2002;Guo et al.2010).Weaver and Broun(2004)reported that the rumen fluid of white-tailed deer had a strong detoxi fication effect on the leaves ofTaxus baccata,reducing the toxicity by 59%.In the Muling forest region,there were only few high-quality ruminant food species in winter.Therefore,red deer ateTaxus baccataduring winter at the cost of greater lignin intake and risk of poisoning.

McDonald et al.(1995)de fined nutritional assessment criteria for diets of ungulates and set a DMD threshold at 50%.Of the 15 species eaten by red deer at Muling,only three had DMD＞50%.These wereE.hyemale,S.manshuricaandA.elata.This suggests that high-quality forage species for wintering red deer in the Muling forest region were relatively few.Alvarado et al.(2012)reported that plant species with higher DMD usually had higher content of other nutrients(e.g.,CP,NFC).In our study,the three plant species that had DMD＞50%also had higher NFC and CP contents,consistent with the results of Alvarado et al.(2012).

The relationship between macronutrients and energy content

Simpson et al.(2003)reported that carbohydrate was an important source of energy for vegetarian insects,while CL content was insigni ficant.Simpson and Raubenheimer(2005)showed that protein can be converted into energy in some cases but at ef ficiency levels of around 15%.Here,NFC was determined as the main energy source of red deer in winter.However,the contribution of CL and CP to energy was negligible.This result supports the conclusions of Simpson et al.(2003)and Simpson and Raubenheimer(2005).

The relationship between fibers and winter diets of red deer

An increase in NDF content is usually accompanied by a reduction in the consumption of nutrients(Xu 2007).Gomez-Castro etal.(2006)considered plantswith NDF＞50%as low-quality food for ungulates(Gomez-Castro et al.2006).Sosa-Rubio et al.(2004)concluded that plants with NDF content between 20 and 35%had higher digestibility(Sosa-Rubio et al.2004).Based on these results,the 15 plants species at Muling could not be considered high-quality food.We recorded low-NDF species such asE.hyemale,S.salicifolia,A.elata,andT.cuspidatethat had high NFC and DMD,consistent with Minson(1990).Minson(1990)concluded that plants with low cell wall content had higher digestible non-structural carbohydrate.Moya-Rodriguez et al.(2002)reported negative correlation between lignin and DMD,which reduced the consumption of food by ungulates.E.hyemale,S.manshurica,andA.elatahad low lignin content and high DMD.This supports the conclusion of Moya-Rodriguez et al.(2002).Therefore,we claim that these three plants species were good-quality food for red deer wintering in the reserve.

Fig.1 The relationship between vegetation energy contents and three macronutrients contents of 15 forage species in the Muling forest region

Fig.2 The composition of fibers(cellulose,hemicellulose and lignin as%of NDF)in 15 forage species by red deer taken from the Muling forest region in winter

Conclusions

There were few high-quality forage species for wintering red deer in the Muling forest region.A.elata,U.pumila,E.alatus,andT.cuspidatehad higher CP content among the 15 forage species whileE.hyemale,S.manshurica,andT.cuspidatehad higher NFC content.Based on their highest CP,NFC,DMD and lowest lignin content,E.hyemale,S.manshurica,andA.elataprovided the best nutritional value for wintering red deer.T.cuspidatewith higher CP and NFC content and higher lignin content,could also be categorized as good-quality forage for red deer.

AcknowledgementsWe are particularly grateful to Qiu Yanming,Dai Fu,Wang Daohui and other staffs at the reserve during the samples collection period.The nutritional composition was carried out by He Huan,Sun Yue,Xing Bo,whose time and competence are gratefully acknowledged.

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