不同年龄大熊猫肠道可培养芽孢杆菌的多样性及部分功能特性分析

【背景】大熊猫的肠道内微生物类群丰富,种群结构与宿主的年龄、生存环境、季节变化等因素有关,其中年龄是影响肠道菌群组成的重要因素之一。【目的】以不同年龄阶段的大熊猫粪便为研究对象,旨在了解不同年龄大熊猫肠道内芽孢杆菌的多样性,探究大熊猫肠道芽孢杆菌种类与年龄段之间的关系,并为优良益生菌剂的开发提供菌种资源。【方法】用稀释涂布法分离大熊猫粪便中的芽孢杆菌,对分离的菌株进行BOXA1R-PCR、16S rRNA基因系统发育及主成分分析,揭示大熊猫肠道中可培养芽孢杆菌的多样性;采用对峙生长法和药敏纸片琼脂扩散法分别检测菌株的抗菌能力和药敏性。【结果】从大熊猫粪便中共分离出90株芽孢杆菌,基于BOXA1R-PCR分析菌株的遗传多样性并从中选取41株代表菌株,经16Sr RNA基因测序分析后,结果显示归属于枯草芽孢杆菌(Bacillus subtilis)、萎缩芽孢杆菌(Bacillus atrophaeus)、贝莱斯芽孢杆菌(Bacillus velezensis)、甲基营养型芽孢杆菌(Bacillusmethylotrophicus)、解淀粉芽孢杆菌(Bacillusamyloliquefaciens)和短小芽孢杆菌(Bacillus pumilus)6个种;主成分分析结果表明大熊猫肠道芽孢杆菌种群组成与年龄存在一定的相关性。所有的供试菌株都具有纤维素降解潜力,大部分菌株对病原菌具有不同程度的抑制作用;除对青霉素具有耐药性外,供试菌株对常见的抗生素耐受性低。【结论】年龄是影响大熊猫肠道芽孢杆菌分布的重要因素,成年大熊猫肠道芽孢杆菌种类多样性最丰富,这为大熊猫益生菌制剂的开发提供了菌种资源。     

九香虫(椿象)体内可培养细菌的多样性分析

【目的】认识药用昆虫九香虫(Aspongopus chinesis Dallas)成虫体内可培养细菌资源多样性。【方法】运用纯培养法、反转录重复因子扩增(BOXA1R-PCR)分析技术、16S r RNA基因测序和系统发育分析对样品中可培养细菌进行多样性研究,测定了分离菌株的抗菌特性、吲哚乙酸(IAA)含量和产淀粉酶活性等指标。【结果】通过6种不同培养基共分离得到52株菌落特征不同的细菌菌株。基于菌落特征和BOXA1R-PCR图谱选取12株代表菌株用于16S r RNA基因序列测定。16S r RNA基因序列系统发育分析显示,52株菌株分属于芽孢杆菌属(Bacillus)、假单胞菌属(Pseudomonas)、寡养单胞菌属(Stenotrophomonas)和伯克霍尔德氏菌属(Burkholderia)4个属,其中芽孢杆菌属(Bacillus)为优势菌属。分离到的52株细菌有44株(占总分离菌株的84.6%)表现出对供试病原菌具有较好的抑制作用,高达94.2%的分离菌株能产IAA,有43株(占总分离菌株的82.7%)表现出淀粉酶活性。【结论】九香虫内细菌种群较为多样,具有潜在应用价值。     

烤烟根际烟碱降解细菌的多样性及其促生特性分析

【背景】挖掘兼具烟碱降解和植物根际促生细菌(Plant Growth-Promoting Rhizobacteria,PGPR)功能的细菌资源,有助于保护土壤质量,实现绿色种植。【目的】分析烤烟根际细菌多样性,筛选可降解高浓度烟碱的PGPR。【方法】采用纯培养法在选择性培养基上分离烟碱降解细菌。通过BOXA1R-PCR分析技术、16SrRNA基因测序及系统发育树构建,对菌株的遗传多样性和分类学地位进行分析。进一步评价了菌株的吲哚乙酸(Indole-3-Acetic Acid,IAA)活性、溶磷能力、病原菌拮抗能力等PGPR指标,以筛选出高效PGPR,最后通过盆栽试验验证其促生效果。【结果】分离得到58株烟碱降解细菌,根据BOXA1R-PCR指纹图谱选取11株菌进行16S rRNA基因序列测定,结果表明,58株菌分别属于芽孢杆菌属(Bacillus)、假单胞菌属(Pseudomonas)、拉乌尔菌属(Raoultella)和短波单胞菌属(Brevundimonas)4个属,以芽孢杆菌属(Bacillus)为优势菌属。58株细菌中48.28%的菌株可产IAA,27.59%具备溶磷能力,37.93%具备纤维素降解能力,G2-13、G2-3及HT2-8因促生与抗病特性突出而被筛选为目标功能菌。盆栽试验结果表明,G2-13菌株对幼苗生长的促进作用明显,可使株高与地上部鲜重分别增加33.05%与53.32%。【结论】烤烟根际存在较为丰富多样的烟碱降解细菌,它们在种植业上具有潜在的应用价值。     

大熊猫肠道放线菌的种群组成及多样性分析

【目的】探究不同年龄、不同性别大熊猫肠道放线菌的多样性及群落结构,为寻找潜在产生活性化合物的放线菌资源提供理论依据。【方法】采用PCR-DGGE技术对大熊猫肠道放线菌进行分析,对电泳结果进行UPGMA聚类分析、主成分分析、生物多样性等多重比较。【结果】变性梯度凝胶电泳(DGGE)图谱显示,不同大熊猫肠道中放线菌的多样性及群落结构存在明显差异。随着年龄的增长,雌性大熊猫肠道中放线菌的多样性指数(H')和丰富度(S)逐渐减少,而雄性大熊猫肠道内放线菌的多样性指数(H')和丰富度(S)逐渐增多。不同个体的大熊猫肠道放线菌的群落结构存在明显差异,但相同性别之间的相似性很高。DGGE条带回收测序结果表明,获得的28条序列归属于10个放线菌属,其中链霉菌属(Streptomyces)为优势菌属,占总数的46%;北里孢菌属(Kitasatospora)、红球菌属(Rhodococcus)、棒杆菌属(Corynebacterium)、迪茨氏菌属(Dietziaceae)、大理石雕菌属(Marmoricola)、布登堡菌属(Beutenbergia)、微杆菌属(Microbacterium)、链嗜酸菌属(Streptacidiphilus)和芽生球菌属(Blastococcus)等为非链霉菌属,占总数的54%。【结论】大熊猫肠道内蕴藏着丰富的放线菌资源,其肠道菌群的结构与组成受年龄和性别的影响。     

猪源乳酸菌的分离、鉴定及其生物学特性

【目的】将分离自猪肠道粘膜、食糜和粪便的乳酸菌,通过产乳酸能力、生长性能、耐酸和耐胆盐性能及抑菌能力评价,筛选适应养猪生产的潜在益生特性的菌株。【方法】共分离获得155株乳酸菌纯菌株,从中筛选出4株产酸能力较强的乳酸菌,结合生理生化试验及细菌16S rRNA测序鉴定其种属,评价候选乳酸菌的生长情况、耐酸、耐胆盐及抑菌特性。【结果】综合变色时间(8 h)、pH值(3.9)和乳酸含量(100 mmol/L),筛选出4株(L45、L47、L63和L79)候选菌株,经鉴定依次为罗伊氏乳杆菌、植物乳杆菌、约氏乳杆菌和粪肠球菌。该4株乳酸菌均可在体外快速生长;L47和L79能够耐受pH 2.5的酸性环境,L47能够耐受0.5%胆盐环境;各乳酸菌上清液与指示菌共培养,发现对E coli K88和沙门氏菌均产生了抑制作用,其中L47上清液对指示菌的抑制作用较强。【结论】L47具有较好的产酸性能与生长性能、可耐受猪胃酸和肠道胆盐环境,对E.coli K88和沙门氏菌具有较好的抑制作用,说明该乳酸菌具有潜在的益生特性。     

内蒙古原始森林桦树皮内生和表生乳酸菌分离鉴定及其特性

【背景】随着乳酸菌产业的快速发展,不同环境乳酸菌群落结构的分析和菌种资源的开发利用已经成为该领域的研究热点。从不同环境、不同来源分离、保藏乳酸菌对于优良菌种的筛选和开发利用具有重要意义。【目的】阐明内蒙古原始森林桦树皮中乳酸菌的组成,并获得丰富的野生型乳酸菌资源,为优良菌株的筛选和工业化应用提供核心菌株,从原始森林桦树皮中分离、鉴定和筛选优良乳酸菌菌种,并研究其特性。【方法】通过传统纯培养方法对20份桦树皮中的内生和表生乳酸菌进行分离纯化,运用16SrRNA基因序列分析以及系统发育关系研究进行种属鉴定,并对样品中的优势菌株进行筛选,得到2株具有优良特性的菌株。【结果】16S rRNA基因序列分析结果表明,分离到的112株乳酸菌鉴定为3个属7个种,其中树皮表生分离株共53株,内生分离株为59株,包括Enterococcusmundtii(27株)、Enterococcusfaecium(16株)、Enterococcusfaecalis(12株)、Enterococcusdurans(1株)、Lactococcuslactis(37株)、Lactococcusgarvieae(18株)、Lactobacillus fermentum (1株)。通过初筛和复筛比较不同乳酸菌在同一条件下的pH和产酸量,从37株Lactococcus lactis中得到2株产酸速率较高、pH较低的乳酸菌,其编号为IMAU98457和IMAU98428。对菌株IMAU98457和IMAU98428进行生物学特性研究,发现其最适生长温度在37°C,适宜pH范围为5.5-7.5,菌株在37°C发酵18 h后菌液OD600值分别高达2.531 0和2.518 2,pH低至4.36和4.34 (总酸)。菌株IMAU98457和IMAU98428有一定的盐耐受性,当NaCl浓度大于6%时,菌株生长受到明显抑制。【结论】20份桦树皮中分离出的112株乳酸菌,Lactococcus lactis (37株)为内蒙古赤峰市桦树皮样品的优势菌株,占总分离株的33%。桦树皮表生样品与内生样品相比,内生样品较表生样品的菌株种类资源更为丰富,二者的优势菌属具有较大的差异,并从优势菌株Lactococcus lactis中筛得2株繁殖速度快、产酸速率较高、pH较低的菌株IMAU98457和IMAU98428。     

耐受微酸性次氯酸水乳酸菌的分离鉴定、耐受特性及益生特性

【背景】次氯酸水具有杀菌性，当其作为饮用水可能会对畜禽肠道内有益菌造成负面影响。【目的】筛选出具有耐受微酸性次氯酸水(slightly acidic hypochlorous acid water, SAHW)能力的乳酸菌并研究其益生特性。【方法】从内蒙古地区传统自然发酵制品中分离筛选出8株乳酸菌菌株，经16SrRNA基因测序进行鉴定。进一步通过耐受SAHW、耐酸、耐胆盐、疏水性及自凝聚能力试验进行耐受特性和益生特性研究。【结果】菌株MBH3-2为副干酪乳杆菌，其经过质量浓度为20mg/L的SAHW处理2h，菌落对数值仅下降0.3lg(CFU/mL)，存活率为50.10%；而且在酸性(pH 2.0、2.5和3.0)、胆盐环境下均可存活；疏水率达62.12%，属于高度疏水性；自凝聚能力在2 h达到97.29%。【结论】最终确定一株具有优良耐受SAHW及基本满足作为微生态制剂要求的菌株，MBH3-2具有作为新型微生态制剂菌株的潜力。     

具有优良抑菌特性乳酸菌的筛选鉴定及活性物质检测

【背景】有益性乳酸菌在人体和动物体内分布极为广泛,是维持胃肠道菌群平衡、提高机体免疫力的主力军。近年来,为了解决禁用抗生素而导致动物发病率不断增高的问题,分析和研究乳酸菌及其所产活性物质的益生特性并开发新型饲料添加剂成为一个重要手段。【目的】本实验旨在从土壤中分离筛选出具有优良抑菌特性的乳酸菌,并对其所产活性物质的特性进行分析评价。【方法】采用溴甲酚紫平板法筛选并结合抑菌能力检测,得到2株具有优良抑菌特性的产酸菌株,分别命名为H-3和H-4。经形态学鉴定及16S rRNA基因序列测定后,对2株菌分别进行生长曲线和产酸量检测;通过排除酸处理、蛋白酶处理和热处理的方法分析2株菌所产抑菌物质的有效成分。【结果】H-3和H-4菌株经初步鉴定为乳酸片球菌(Pediococcus acidilactici),2株菌均具有良好的生长性能及产酸性能。菌株发酵上清液对大肠杆菌(Escherichia coli)、金黄色葡萄球菌(Staphylococcus aureus)、猪霍乱沙门氏菌(Salmonella choleraesuis)、福氏志贺氏菌(Shigella flexneri)均表现出明显的抑...     

牦牛源产细菌素屎肠球菌的分离鉴定和益生特性

【背景】抗生素的滥用导致牦牛肠道常见病原菌耐药性增加,益生菌作为对抗耐药性细菌的新型武器,应用前景广阔。【目的】获取益生特性优良的牦牛源益生菌。【方法】将20份牦牛粪便样本在含0.5%CaCO3的MRS培养基上分离纯化,以大肠杆菌和金黄色葡萄球菌为指示菌,用牛津杯法筛选有抑菌活性的菌株;排除酸和过氧化氢后,经耐酸耐热试验和蛋白酶敏感试验筛选产细菌素菌株,用形态学和16S rRNA基因序列分析鉴定;通过对大肠杆菌、沙门氏菌等腹泻病原菌体外抑菌试验、耐模拟胃肠液、测定自聚集能力和疏水性及抗生素敏感试验分析益生特性。【结果】从20份牦牛粪便样本中共分离出11株产生溶钙圈的菌株,其中6株对大肠杆菌和金黄色葡萄球菌抑菌效果显著,经复筛得到2株产细菌素的乳酸菌SC6和SC9,经鉴定均为屎肠球菌(Enterococcus faecium)。其中SC9对腹泻病原菌抑菌效果明显,有良好的耐受性和肠道黏附能力,对5种常用抗生素均敏感。【结论】屎肠球菌SC9有一定的抗逆性和潜在的益生能力,具备作为益生菌的潜力。     

大熊猫粪便乳酸菌的分离鉴定

大熊猫作为国家保护动物,其健康问题备受瞩目。为了维护大熊猫的肠道健康,本研究从大熊猫肠道内分离出适宜于大熊猫肠道环境的乳酸菌菌株,有望将其制成熊猫肠道微生物制剂,从而改善大熊猫肠道菌群环境。从雅安市宝兴县蜂桶寨自然保护区选取圈养与野生大熊猫的粪便,通过体外培养分离出9个菌株。分离菌株经过革兰氏染色镜检、过氧化氢产气、菌落形态观察等方法与技术初步鉴定为乳酸菌。对这9株乳酸菌进行耐酸试验、耐胆盐试验、抑菌能力试验和产酸能力等测试,筛选出了3个适应性较强,有望制成调节大熊猫肠道内环境平衡作用的微生态菌剂的菌株。16S rRNA基因序列分析表明:分离菌株J1、J2和J4分别为融合魏斯氏菌（Weissella confusa）,海氏肠球菌（Enterococcus heynei）和非解乳糖链球菌（Streptococcus alactolyticus）,有望被应用于大熊猫肠道微生态制剂的研究。     

大熊猫精液和包皮菌群组成及潜在致病菌调查

[目的] 大熊猫是我国国家一级保护动物,其种群面临着传染病和栖息地破碎化等持续威胁,其中生殖系统的细菌感染和菌群失衡会影响大熊猫生殖健康,严重者可导致流产,是引起大熊猫繁殖障碍的原因之一。本研究对精液与包皮分泌物样本的菌群组成情况及分离培养潜在致病菌开展研究。[方法] 通过采集13份大熊猫包皮分泌物和12份精液样本,采用16S rRNA扩增子测序技术、细菌培养及PCR鉴定的方法,确定样本中的细菌种类。[结果] 菌群组成分析结果显示,在门水平上,厚壁菌门（Firmicutes）的细菌丰度在大熊猫包皮与精液中均为最高;在属水平上,不同时期的雄性大熊猫包皮的菌群可能会发生改变,棒状杆菌属（Corynebacterium）和Dolosicoccus是Ⅰ期包皮样本中最丰富的微生物菌群,相对丰度分别为15.45%和12.40%;链球菌属（Streptococcus）和埃希氏菌属（Escherichia）是Ⅱ期包皮样本中最丰富的微生物菌群,相对分度分别为37.94%和9.68%;拟杆菌属（Bacteroides）和普雷沃氏菌属（Prevotella）是精液样本中最丰富的微生物菌群,相对丰度分别为14.40%和12.88%。菌群多样性分析结果显示,精液样品高于Ⅰ期包皮样品和Ⅱ期包皮样品,Ⅰ期包皮样品和Ⅱ期包皮样品之间无显著差异。通过细菌分离培养得到肺炎克雷伯菌（Klebsiella pneumonia）在内的多种潜在性致病菌。[结论] 本研究分析了大熊猫精液和不同时期包皮分泌物的菌群组成,其优势菌属存在差异,大熊猫包皮与精液中存在潜在性致病菌,这可能对大熊猫的生殖系统健康带来威胁,其致病性有待进一步研究。     

大熊猫源肺炎克雷伯菌生物学特性

【背景】肺炎克雷伯菌是仅次于大肠杆菌的常见条件致病菌之一,严重时可导致大熊猫发生出血性肠炎、全身性败血症等。【目的】明确大熊猫源肺炎克雷伯菌的生物学特性,对防控该病作出科学指导。【方法】分别采用结晶紫染色法、拉丝实验、K-B纸片法和PCR技术对46株大熊猫源肺炎克雷伯菌的生物被膜形成能力、高黏性表型、耐药表型和15种常见毒力基因等生物学特性进行研究,并根据以上生物学特性选择一株可能具有致病性的分离菌pneumoniae-X-5,研究其对小鼠的致病性。【结果】46株肺炎克雷伯菌均可形成荚膜;12株为高黏性表型肺炎克雷伯菌;能形成生物被膜的菌株占比为65%(30/46);分离出的46株菌中多重耐药菌株占58%(27/46),对氨苄西林、苯唑西林、青霉素、万古霉素呈100%耐药;毒力基因检出率最高的为ureA(91.30%,42/46)。pneumoniae-X-5菌株对小鼠的LD₅₀为8.9×10⁴CFU/mL;该菌株攻毒小鼠肺泡间隔增厚,炎性细胞浸润,肝细胞变性坏死,脾充血,十二指肠黏膜上皮和固有层分离,固有层部分细胞坏死。死亡小鼠脾脏含细菌量最多,其次为肝脏。【结论】本试验阐明了部分大熊猫源肺炎克雷伯菌的多重耐药性、能形成生物被膜、具有高黏表型等病原生物学特性,为大熊猫肺炎克雷伯杆菌病的防控及临床治疗提供了科学依据。     

全基因组测序揭示两株泡菜源植物乳杆菌基因型差异和潜在益生特性北大核心

【目的】为了探究植物乳杆菌(Lactiplantibacillus plantarum)基因型差异和潜在益生特性,采用全基因组测序技术对其进行测序并解析基因组序列及生物特性。【方法】本研究基于HiSeq和PacBio测序平台,对团队前期从四川多代泡菜中分离获得、体外益生特性评价良好的潜在益生菌菌株L.plantarum Eden-Star PC06和L.plantarum Eden-Star PC108的全基因组进行测序。利用相关生物信息学软件对原始数据进行组装及其后续的功能注释、分子进化、菌株安全性、次级代谢产物合成基因簇以及益生特性相关基因进行分析。【结果】通过基因组装得到了2株植物乳杆菌的全基因组信息,L.plantarum Eden-Star PC06和Eden-Star PC108基因组大小分别为3163902 bp和3205054 bp;GC含量分别为44.68%和44.67%;分别包含3161个和3197个DNA编码序列;功能基因数据库比对结果显示2株菌在碳水化合物利用、氨基酸利用和糖基转移酶等基因上得到大量注释;通过比对数据库,在2株植物乳杆菌全基因组上发现了4个与肠液耐受相关的胆盐水解酶基因、完整的植物乳杆菌细菌素合成相关基因簇和抵御多种胁迫的益生相关基因。【结论】本研究通过全基因组测序在基因水平上探究了L.plantarum Eden-Star PC06和Eden-Star PC108基因型差异和益生特性基因,证明L.plantarum Eden-Star PC06和Eden-Star PC108是2株有应用前景的益生菌菌株,以期为筛选优良益生菌菌株和评价其益生特性提供遗传学基础。     

Preliminary investigation on iodine nutrition in captive giant pandas

Background/ObjectiveThe giant panda belongs to the family Ursidae and, as a species of bear, still retains the simple digestive system of a Carnivoran. However, under the pressure of a specific habitat they had to adapt to a plant mono-diet consisting of bamboo with different species and growth stages around the year. A plant-based diet has relatively low iodine content with risk of iodine deficiency. Furthermore, bamboo contains cyanogenic glycosides releasing cyanide whose detoxification metabolite the thiocyanate acts as antagonist against iodine uptake and storage in the thyroid. To date very little is known about the iodine nutritional status of the giant panda, thus this study was conducted to receive the first information about the iodine nutrition of captive giant panda.Subjects/MethodsHere we investigated the iodine content of bamboo with different plant parts/vegetation stage and species and further compounds of the captive giant panda diet. Next, the urinary iodine (UI) and urinary thiocyanate (UT) levels of infant, sub-adult, adult and geriatric captive giant pandas was measured during the periods when the pandas consume both bamboo leaves- and culm (bamboo leaf-culm stage). Afterwards, the UI of 19 adult giant pandas was measured again for the different iodine intake during bamboo shoot stage. Finally, in this study part also the fecal iodine concentration was analyzed for calculation of total iodine excretion in relation to the iodine intake.ResultsBamboo leaves had the highest iodine content (453 μg/kg dry matter (DM)), followed by the shoots (84 μg/kg DM, p < 0.05), while bamboo culm had the lowest value (12 μg/kg DM, p < 0.05). During bamboo leaf-culm stage, giant pandas of different age groups had different UI and UT levels (p < 0.05). Furthermore, UI and UT were positively correlated among sub-adult, adult and geriatric giant pandas (p < 0.05). In adult giant pandas during bamboo shoot stage, the iodine excretion in feces was not different from that in urine while their total iodine excretion was less than their iodine intake (p < 0.05). Moreover, during bamboo shoot stage, the UI level of adult giant pandas was much lower than noted during bamboo leaf-culm stage (p < 0.05).ConclusionsOur results indicate that UI of captive giant pandas was related to their age as well as to the vegetation stage/part of bamboo they consumed reflecting a different periodic iodine supply. Thiocyanate and fecal excretion should be emphasized when considering the iodine nutrition of giant pandas.     

Gut microbiota in reintroduction of giant panda

Reintroduction is a key approach in the conservation of endangered species. In recent decades, many reintroduction projects have been conducted for conservation purposes, but the rate of success has been low. Given the important role of gut microbiota in health and diseases, we questioned whether gut microbiota would play a crucial role in giant panda's wild‐training process. The wild procedure is when captive‐born babies live with their mothers in a wilderness enclosure and learn wilderness survival skills from their mothers. During the wild‐training process, the baby pandas undergo wilderness survival tests and regular physical examinations. Based on their performance through these tests, the top subjects (age 2–3 years old) are released into the wild while the others are translocated to captivity. After release, we tracked one released panda (Zhangxiang) and collected its fecal samples for 5 months (January 16, 2013 to March 29 2014). Here, we analyzed the Illumina HiSeq sequencing data (V4 region of 16S rRNA gene) from captive pandas (n = 24), wild‐training baby pandas (n = 8) of which 6 were released and 2 were unreleased, wild‐training mother pandas (n = 8), one released panda (Zhangxiang), and wild giant pandas (n = 18). Our results showed that the gut microbiota of wild‐training pandas is significantly different from that of wild pandas but similar to that of captive ones. The gut microbiota of the released panda Zhangxiang gradually changed to become similar to those of wild pandas after release. In addition, we identified several bacteria that were enriched in the released baby pandas before release, compared with the unreleased baby pandas. These bacteria include several known gut‐health related beneficial taxa such as Roseburia, Coprococcus, Sutterella, Dorea, and Ruminococcus. Therefore, our results suggest that certain members of the gut microbiota may be important in panda reintroduction.     

Synergistic effects of anthropogenic disturbances on giant pandas

Livestock grazing and the collection of bamboo shoots are the main threats to giant panda (Ailuropoda melanoleuca) habitat in the Liangshan Mountains in China. It is important to clarify the effect of these disturbances to the giant panda to formulate targeted management policies. Based on species distribution models and daily activity models, we investigated the effects of livestock grazing and bamboo shoot collection on giant pandas from May 2021 to July 2022. Our results indicated the giant panda's suitable habitat in the reserve covered 51.83 km² (15.02% of the reserve area). Grazing and bamboo shoot collection led to losses of 19.08 km² and 7.68 km² of suitable habitat, respectively. Together, the 2 activities resulted in a loss of 28.35 km² of suitable habitat, which was more than half of the area of panda habitat. The areas of suitable habitat for giant pandas significantly overlapped with the areas affected by both disturbances. Giant pandas did not show significant differences in daily activity rhythms under a single disturbance, but the daily activity rhythms of giant pandas differed when we compared the area combining the 2 disturbances with the undisturbed area. Our study reveals that the anthropogenic disturbances in the reserve have varying effects on the suitable habitat range and daily activity rhythm of giant pandas and evidence of a synergistic effect. Therefore, when formulating relevant conservation policies, it is important to fully evaluate the extent and characteristics of anthropogenic disturbances in shaping the population distribution and habitat preferences of the giant panda and other wildlife to enhance the efficacy of conservation management practices.