小鼠Peroxiredoxin 6基因克隆、原核表达及多克隆抗体的制备

过氧化物氧还酶6(peroxiredoxin6,Prdx6)是一种双功能蛋白质,具有GSH过氧化物酶和磷脂酶A2活性。前期研究构建布鲁氏菌强弱毒株感染绵羊白细胞层SSH c DNA文库,发现Prdx6在不同毒力布鲁氏菌感染时存在一定的差异性表达,推测Prdx6可能在布鲁氏菌感染中发挥一定的作用。为了更好地研究其在生物体中的作用,以RT-PCR技术,提取小鼠巨噬细胞系RAW264.7总RNA,反转录制备c DNA,设计特异引物克隆Prdx6开放阅读框核酸序列,并构建原核表达载体,进行原核表达,以镍柱纯化获得纯度较高的Prdx6蛋白,免疫家兔制备高特异性、高灵敏度的鼠Prdx6兔源多克隆抗体,为后续进一步研究Prdx6蛋白功能提供科学依据和应用工具。     

血管内皮生长因子蛋白在大鼠睾丸和附睾的表达和定位研究

为探讨血管内皮生长因子(VEGF)在雄性生殖系精子发生发育和成熟过程中的调控作用,应用免疫组化、Periodic acid-Schiff(PAS)染色及蛋白质免疫印迹技术,检测VEGF蛋白在成年大鼠睾丸和附睾的表达和定位情况。Western-blots显示,在大鼠睾丸和附睾内均有VEGF蛋白(约45kD)的表达;免疫组化显示,睾丸内VEGF见于圆形和长形精子细胞、Sertoli细胞和Leydig细胞,免疫阳性产物位于细胞质内。精子细胞的VEGF表达伴随精子细胞顶体发育的全过程,精子残余体呈强阳性。附睾内VEGF表达于附睾管上皮,且有区域和细胞特异性。附睾起始段的所有上皮主细胞内都有VEGF阳性颗粒;头、体、尾各段的VEGF阳性细胞多数与含PAS阳性颗粒的细胞重合,证明为亮细胞;近端附睾的管腔内可见精子头部呈VEGF阳性染色。睾丸、附睾间质血管内皮为VEGF阴性。上述结果表明,VEGF蛋白可由生殖细胞和附睾管上皮细胞直接产生,它可能以自分泌和/或旁分泌的形式共同作用于睾丸和附睾的生殖细胞和血管内皮,直接或间接影响精子的发生、发育和成熟过程,特别是精子顶体的形成过程,并可能与精子在附睾内的成熟有关。     

血管内皮生长因子蛋白在大鼠睾丸和附睾的表达和定位研究

为探讨血管内皮生长因子(VEGF)在雄性生殖系精子发生发育和成熟过程中的调控作用,应用免疫组化、Periodic acid-Schiff(PAS)染色及蛋白质免疫印迹技术,检测VEGF蛋白在成年大鼠睾丸和附睾的表达和定位情况。Western-blots显示,在大鼠睾丸和附睾内均有VEGF蛋白(约45kD)的表达;免疫组化显示,睾丸内VEGF见于圆形和长形精子细胞、Sertoli细胞和Leydig细胞,免疫阳性产物位于细胞质内。精子细胞的VEGF表达伴随精子细胞项体发育的全过程,精子残余体呈强阳性。附睾内VEGF表达于附睾管上皮,且有区域和细胞特异性。附睾起始段的所有上皮主细胞内都有VEGF阳性颗粒;头、体、尾各段的VEGF阳性细胞多数与含PAS阳性颗粒的细胞重合,证明为亮细胞;近端附睾的管腔内可见精子头部呈VEGF阳性染色。睾丸、附睾间质血管内皮为VEGF阴性。上述结果表明,VEGF蛋白可由生殖细胞和附睾管上皮细胞直接产生,它可能以自分泌和／或旁分泌的形式共同作用于睾丸和附睾的生殖细胞和血管内皮,直接或间接影响精子的发生、发育和成熟过程,特别是精子顶体的形成过程,并可能与精子在附睾内的成熟有关。     

叶酸-壳聚糖Prdx6 shRNA纳米粒的构建及其对胃癌细胞增殖的影响

目的:探讨叶酸-壳聚糖Prdx6 shRNA纳米粒对胃癌细胞生长的影响。方法:制备靶向性叶酸-壳聚糖Prdx6 shRNA纳米粒,原子力显微镜观察其形态,激光粒度分析仪测定纳米粒的粒径;倒置荧光显微镜观察叶酸-壳聚糖Prdx6 shRNA纳米粒的转染效率;采用蛋白质印迹法检测胃癌细胞Prdx6蛋白的表达变化;CCK8细胞增殖实验检测胃癌细胞的存活率。结果:1制备成功叶酸-壳聚糖Prdx6 shRNA向纳米粒。2荧光显微镜下观察靶向性叶酸-壳聚糖Prdx6 shRNA纳米粒转染胃癌细胞的效率明显高于非靶向纳米粒;胃癌细胞转染靶向组纳米粒后Prdx6蛋白的表达显著低于非靶向组。3与对照组相比,叶酸-壳聚糖Prdx6 shRNA纳米粒能够明显抑制胃癌细胞的增殖(P0.01)。结论:1叶酸-壳聚糖Prdx6 shRNA纳米粒可高效转染胃癌细胞。2转染叶酸-壳聚糖Prdx6 shRNA纳米粒后胃癌细胞的生长明显受抑制。     

大鼠附睾蛋白质组的提取和二维液相色谱分离

背景与目的：提取犬鼠附睾液蛋白并建立一种利用二维液相色谱法分离附睾蛋白组的方法。方法：分离提取犬鼠附睾液蛋白。样品利用起始缓冲液置换后,进行一维色谱聚焦分离,然后收集pH8．5—4．0之间的组份进行二维反相离压液相色谱分离,最后将获得的二维UV图通过ProteoVue软件转换成PI／UV图谱。结果：成功提取了附睾液蛋白,并通过二维液相色谱成功建立了大鼠头体尾部附睾液蛋白的二维PI／UV图谱,收集了一维色谱聚焦分离的pH8．5—4．0区间的20个组份,并将每个组份进行二维色谱分离后转换为PI/UV图谱。结论：为进一步全面研究附睾蛋白功能和体液差异蛋白质组研究打下了基础。     

血-附睾屏障的电生理学及超微结构研究

用玻璃微电极记录大鼠跨附睾上皮细胞电位差。附睾头,附睾体和附睾尾的电位差分别为-5.61±0.42,-4.36±0.38和-4.12±0.23毫伏,腔内为负(均值±S.E.)。用接近生理渗透压(360 mOsm/kg·水),含2%硝酸镧示踪物的灌流液分别从大鼠精索内动脉和附睾管腔内灌流,观察到附睾上皮细胞之间的各种结构形式的连接复合体是血一附睾屏障的超微结构位点。证明小分子的硝酸镧可以通过五合式或纤维式的连接结构,但不能通过附睾上皮细胞间的桥粒复合体和间隙连接。并从生理学和形态学上均证明有血-附睾屏障的存在。棉酚处理后(30毫克/公斤体重/日),附皋的跨上皮电位差的绝对值降低。附睾头,附睾体及附睾尾分别为3.58±0.23,4.13±0.27和3.03±0.18毫伏,腔内为负。其中附睾头与附睾尾的电位变化有明显的统计学意义。附睾上皮细胞对硝酸镧的通透性也稍有增加。     

猴ESc—615基因重组蛋白质片段的表达纯化和多克隆抗体的制备

ESc 6 15是从猕猴中克隆到的一个在附睾中特异性表达的新基因。为了从蛋白质水平深入研究其在精子成熟中的作用 ,在大肠杆菌中表达了该蛋白质的一条含 310个氨基酸的肽段 ,并用其免疫新西兰大白兔 ,得到了滴度为 10 0 0 0 0的抗血清 ;用Western印迹方法鉴定发现该抗血清可检测到 3ng的抗原量 ;并在大鼠附睾组织抽提液中检测到一种能与该抗血清作用的大小约 6 3kD的蛋白质 ,此蛋白质大小与作者实验室在大鼠中克隆到的此基因的同源蛋白质相同 ;利用该抗体通过免疫组化分析确定了ESc 6 15为分泌蛋白质 ,并能与精子结合 ;该抗血清经抗原吸附后阳性结果消失。该高滴度多克隆抗体的获得为ESc 6 15功能的探索提供了一条途径。     

VEGF、VEGFR2在青春期大鼠睾丸、附睾及附睾精子上的表达

目的通过对血管内皮生长因子(VEGF)及其受体VEGFR2在青春期大鼠睾丸及附睾表达的研究,探讨其在雄性生殖器官中的作用。方法采用免疫组化法检测VEGF、VEGFR2在SD大鼠睾丸和附睾的表达定位,用免疫荧光法检测它们在大鼠附睾精子上的表达定位。结果VEGF及VEGFR2在青春期大鼠睾丸和附睾组织中均有表达。在睾丸中,VEGF主要表达于精原细胞胞质、精子细胞发育中的顶体、Sertoli细胞胞质及精子残余体内,Leydig细胞胞质也有阳性表达;VEGFR2主要表达于精子细胞发育中的顶体和间质细胞胞质。在附睾中,VEGF表达于附睾管上皮所有主细胞胞质内;而VEGFR2表达于附睾管头段和尾段上皮主细胞胞质内,体段免疫染色阴性。免疫荧光显示,VEGF与VEGFR2都与精子头部顶体、尾部颈段、中段和主段相结合,末段未见阳性荧光。结论VEGF及VEGFR2在大鼠的睾丸和附睾中均有表达,其表达定位具有细胞特异性和区域特异性,提示其可能在大鼠睾丸精子发生和附睾精子成熟中发挥重要作用。     

基质Gla蛋白在大鼠附睾发育过程中的表达及定位

目的明确基质Gla蛋白(matrix Gla protein,MGP)在大鼠附睾发育过程中的表达特征。方法采用实时定量PCR和免疫荧光染色方法,对MGP在大鼠附睾不同发育阶段的表达及定位进行检测。结果实时定量PCR结果显示,MGP mRNA在6d、10d、3w、5w、7w、8w、10w和12w的大鼠附睾中均有表达,其表达量在3w达到最高峰,3w至8w表达量逐渐降低,成年大鼠(10～12w)MGP的表达量逐渐升高并稳定在较高水平。免疫荧光染色显示MGP在10d、3w的大鼠附睾各个节段均有表达,在7w、12w的表达主要集中于大鼠附睾体部和尾部,且MGP定位于附睾上皮主细胞和亮细胞。结论MGP在大鼠附睾发育的关键分化期高表达,成年后主要定位于附睾体部和尾部的主、亮细胞,可能对附睾的形态发育和管腔钙稳态的维持起重要作用。     

附睾蛋白的研究方法及进展

附睾是精子成熟,转运和贮存的场所,哺乳动物精子成熟是通过与附睾管腔微环境相互作用而实现的,精子通过在附睾内转运过程中与附睾蛋白相互作用获得运动和精卵识别结合能力,因而附睾蛋白的研究受到越来越多的关注.本文从不同的实验角度综述了附睾蛋白的研究方法及其进展.     

Changes in protein composition of the luminal fluids along the epididymis of the tammar, Macropus eugenii

Micropuncture samples of luminal fluid were collected from the rete testis and along the epididymis. Quantitative analyses showed that the ductuli efferentes reabsorb about half the protein leaving the testis. Considerable protein is secreted by the caput epididymidis (initial segment) and there is a net loss of protein from the corpus and cauda epididymidis. Denatured, polyacrylamide gel electrophoresis showed that there are 5 proteins in rete testis fluid which are not present in blood (Mr of 14,700, 22,800, 24,100, 43,000 and 44,800). One of these proteins (Mr 14,700) is lost from plasma in the ductuli efferentes and 2 (Mr 43,200 and 44,800) are lost in the corpus epididymidis. Twelve proteins appear in the epididymal plasma and are not present in rete testis fluid or blood: 6 appear in the caput epididymidis (Mr 30,000, 31,000, 32,300, 17,400, 18,700 and 21,400), 3 in the corpus epididymidis (Mr 12,800, 39,800 and 90,600) and 3 in the cauda epididymidis (Mr 10,900, 56,300 and 63,000). A protein with the same molecular weight as a blood protein (149,500) accumulates in the corpus and cauda epididymidis. None of the samples of luminal fluid contained particulate matter other than spermatozoa, indicating that the tammar is a useful animal for micropuncture studies.     

Effects of caput ligation on rat sperm and epididymis: protein thiols and fertilizing ability.

Mammalian spermatozoa mature while passing through the epididymis. Maturation is accompanied by thiol oxidation to disulfides. In rats, sperm become motile and fertile in the cauda. We have previously demonstrated that rat caput sperm contain mostly thiols and that upon passage from the corpus to the cauda epididymidis, sperm protein thiols are oxidized. The present work was undertaken to study the role of the regions of the epididymis in sperm maturation as reflected in the thiol status, fertility, and motility of the spermatozoa. The distal caput epididymidis of mature albino rats was ligated on one side. After 5 days, sperm were isolated from the ligated caput and from caput and cauda of the control side. Thiol groups in sperm, epididymal luminal fluid (EF), and epididymal tissue were labeled using the fluorescent thiol-labeling agent monobromobimane. After ligation, changes were observed in a) sperm proteins, sperm nuclear proteins, and epididymal fluid by electrophoresis; b) epididymal tissues by histochemistry; c) progressive motility by phase microscopy; and d) fertilizing ability after insemination into uteri of immature females. We found that after ligation, caput sperm thiols, especially protamine thiols, are oxidized, rendering them similar to mature sperm isolated from the cauda epididymidis. Spermatozoa from ligated caput epididymidis gain progressive motility and partial fertilizing ability. Morphology of epithelial cells of ligated caput is similar to that of cauda cells. However, other changes in caput EF and epithelium induced by ligation render the ligated caput epididymidis different from either control caput or cauda. Hence, sperm thiol oxidation, along with the development of fertilizing ability, can occur in sperm without necessity for sperm transit through the corpus and cauda epididymidis.     

Comparison between epididymosomes collected in the intraluminal compartment of the bovine caput and cauda epididymidis

During their transit along the epididymidis, mammalian spermatozoa acquire new proteins involved in the acquisition of male gamete fertilizing ability. We previously described membranous vesicles called epididymosomes, which are secreted in an apocrine manner by the epididymal epithelium. Some selected proteins associated with epididymosomes are transferred to spermatozoa during epididymal transit. The present study compared epididymosomes collected from caput epididymal fluid with vesicles from the cauda epididymidis in the bull. Two-dimensional gel electrophoresis revealed major differences in protein composition of epididymosomes isolated from the caput and cauda epididymidis. LC-QToF analysis of major protein spots as well as Western blot analysis confirmed the differences in proteins associated with these two populations of epididymosomes. Biotinylated proteins associated with caput and cauda epididymosomes also revealed differences. When incubated with caput epididymal spermatozoa, epididymosomes prepared from these two segments transferred different protein patterns. By contrast, cauda epididymosomes transferred the same pattern of proteins to spermatozoa from the caput and cauda epididymidis. Transfer of biotinylated proteins from cauda epididymosomes to caput spermatozoa decreased in a dose-dependent manner when biotinylated epididymosomes were diluted with unbiotinylated vesicles. Caput epididymosomes added in excess were unable to inhibit transfer of biotinylated proteins from cauda epididymosomes to caput spermatozoa. Following transfer of biotinylated proteins from cauda epididymosomes to caput spermatozoa, addition of unbiotinylated cauda epididymosomes was unable to displace already transferred biotinylated proteins. These results established that epididymosomes from caput and cauda epididymidis have different protein composition and interact differently with maturing spermatozoa.     

Interactions of labeled epididymal secretory proteins with spermatozoa after injection of 35S-methionine in the mouse

The sequential interactions of epididymal secretory proteins with spermatozoa during epididymal transit were examined. Mice received injections of 35S-methionine, and the radiolabeled luminal fluid and sperm-associated proteins were analyzed by sodium dodecylsulfate-polyacrylamide gel electrophoresis at various times after injection. The majority of the luminal fluid and sperm-associated proteins were found in the caput epididymidis at 8 h; by 7 days, many of these proteins had been transported to the cauda epididymidis. Two classes of epididymal protein-sperm interactions were distinguished on the basis of regional synthesis and secretion. The major class consisted of proteins that were synthesized, secreted, and bound to spermatozoa in the caput epididymidis. In this class, however, the binding of proteins to the spermatozoa was variable. For example, a protein of 25 kDa remained associated with spermatozoa in substantial amounts during epididymal transit, while proteins of 40 and 35 kDa decreased in amount. Other proteins such as a protein of 18 kDa did not remain associated with spermatozoa. Another class of proteins (54, 44, 29 kDa) were synthesized and secreted from all epididymal regions but bound only to caput spermatozoa. Most of the epididymal proteins appeared to be tightly bound to the spermatozoa since spermatozoa already saturated with the unlabeled protein in the distal epididymis remained so even though the spermatozoa were surrounded by labeled proteins in the luminal fluid. These studies demonstrate that a variety of specific interactions occur between epididymal secretory proteins and spermatozoa as they migrate and mature in the epididymis.     

Immunocytochemical localization of the major glycoprotein of epididymal fluid from the cauda in the epithelium of the mouse epididymis

Summary The most abundant protein in fluid from the mouse cauda epididymidis, designated CP 27, is a glycoprotein that migrates at approximately 27000 daltons on SDS-polyacrylamide gels. Samples of CP 27 were isolated by preparative gel electrophoresis and were used to raise a guinea-pig polyclonal antiserum, which reacted with a single band on western blots of caudal epididymal fluid. This antiserum was used for immunocytochemical localization of CP 27 in histological sections of mouse epididymis using the peroxidase-antiperoxidase and protein A-gold methods. The most proximal staining with anti-CP 27 was in segment 6 of the distal caput epididymidis, where the lumen and a portion of the supranuclear cytoplasm of principal cells were stained. In contrast, in the distal corpus and cauda epididymidis (segments 8–11), there was pronounced staining of the luminal contents, stereocilia, and scattered cells identified as the light cells of the epididymal epithelium. Although CP 27 was found in the epididymal lumen of all segments distal to segment 6, the intensity of staining appeared to decline distally in the cauda epididymidis. Control sections exposed to pre-immune serum instead of anti-CP 27 showed no reaction. The results suggest that CP 27, the major glycoprotein of cauda epididymal fluid, is synthesized by principal cells of segment 6 of the distal caput epididymidis. CP 27 may be among the substances absorbed from the lumen by the light cells of the distal epididymis.     

A 105- to 94-kilodalton protein in the epididymal fluids of domestic mammals is angiotensin I-converting enzyme (ACE); evidence that sperm are the source of this ACE

SDS-PAGE analysis of luminal fluid from the ram testis and epididymis revealed a protein of about 105 kDa in the fluid in the caput epididymal region. The molecular mass of this fluid protein shifted from 105 kDa to 94 kDa in the distal caput epididymidis and remained at 94 kDa in the lower regions of the epididymis. The possible sperm origin of this protein was suggested by the decrease in intensity of a 105-kDa compound on the sperm plasma membrane extract and by its total disappearance from the fluid of animals with impaired sperm production caused by scrotal heating. The 94-kDa protein was purified from ram cauda epididymal fluid, and a rabbit polyclonal antiserum was obtained. This antiserum showed that membranes of testicular sperm and sperm from the initial caput were positive for the presence of an immunologically related antigen. The protein was immunolocalized mainly on the flagellar intermediate piece, whereas in some corpus and caudal sperm, only the apical ridge of the acrosomal vesicle was labeled. The purified protein was microsequenced: its N-terminal was not found in the sequence database, but its tryptic fragments matched the sequence of the angiotensin I-converting enzyme (ACE). Indeed, the purified 94-kDa protein exhibited a carboxypeptidase activity inhibited by specific blockers of ACE. All the soluble seminal plasma ACE activity in the ram was attributable to the 94-kDa epididymal fluid ACE. The polyclonal antiserum also showed that a soluble form of ACE appeared specifically in the caput epididymal fluid of the boar, stallion, and bull. This soluble form was responsible for all the ACE activity observed in the fluid from the distal caput to the cauda epididymidis in these species. Our results strongly suggest that the epididymal fluid ACE derives from the germinal form of ACE that is liberated from the testicular sperm in a specific epididymal area.     

Resorption versus secretion in the rat epididymis

Micropuncture samples were taken from the rete testis, caput epididymidis and cauda epididymidis of anaesthetized adult rats and assayed for total protein, sodium and potassium concentrations. Intraluminal sperm concentrations were determined and used to calculate the amount of fluid resorbed from the efferent duct and epididymal lumen. It was demonstrated that large amounts of protein (30.2 mg/ml cauda volume) and sodium (241.8 mequiv./l) and smaller amounts of potassium (19.4 mequiv./l) are resorbed from the rat epididymal lumen between the caput and corpus epididymidis. This occurs despite increases in intraluminal concentrations of protein (from 22 to 28 mg/ml) and potassium (from 16 to 50 mequiv./l). Resorption is an important aspect of epididymal control of the intraluminal environment.     

Two-dimensional electrophoresis of proteins in principal cells, spermatozoa, and fluid associated with the rat epididymis

Spermatozoa, fluids, and principal cells from different regions of the epididymis were characterized by two-dimensional electrophoresis. Rete testis fluid was collected after 36-h efferent duct ligation, and cauda epididymal fluid was collected by retrograde perfusion through the vas deferens. Spermatozoa were collected after their exudation from minced caput and corpus epididymal tissue. Principal cells were recovered after enzymatic disaggregation and centrifugal elutriation of epididymides. Two-dimensional polyacrylamide gel electrophoresis was used to prepare protein profiles of all samples. Comparison of the proteins found in rete testis fluid versus those found in cauda epididymal fluid revealed a dramatic change in composition, including the loss, addition, or retention of specific proteins as well as changes in the relative concentrations of certain proteins. Prominent cauda epididymal fluid proteins, possibly contributed by the epididymal epithelium, were detected at 16, 23, and 34 kDa. After epididymal transit, a considerable decrease was observed in the number of aqueous-soluble sperm proteins. Differences in the protein composition of epididymal epithelial principal cells from the caput versus corpus epididymidis were also noted, suggesting that functional differences exist for these epididymal regions. Of particular interest was the occurrence of a prominent protein of approximately 20-23 kDa found in all sperm samples, in fluids, and in caput and corpus principal cells. However, this protein was absent in cauda epididymal sperm after 36-h efferent duct ligation. The rapid loss of this protein from sperm after efferent duct ligation suggests that this surgical intervention may affect spermatozoa residing within the epididymis.     

Biochemical characterization of two ram cauda epididymal maturation-dependent sperm glycoproteins

Rabbit polyclonal antibodies were raised against ram cauda epididymal sperm proteins solubilized by N-octyl-beta-D-glucopy-ranoside (anti-CESP) and against proteins of the fluid obtained from the cauda epididymidis (anti-CEF). The anti-CESP polyclonal antibody reacted with several bands from 17 to 111 kDa with different regionalization throughout the epididymis. The strongest epitopes at 17 kDa and 23 kDa were restricted to the cauda epididymidis. The anti-CEF polyclonal antibody reacted mainly with a 17-kDa and a 23-kDa compound in the cauda sperm extract. These cauda epididymal 17- and 23-kDa proteins disappeared after orchidectomy, but they reappeared in the same regions after testosterone supplementation, indicating that they were secreted by the epithelium. The fluid and membrane 17- and 23-kDa antigens had a low isoelectric point and were glycosylated. The fluid 17- and 23-kDa proteins had hydrophobic properties: they were highly enriched in the Triton X-114 detergent phase and could be extracted from the cauda epididymal fluid by a chloroform-methanol mixture. These proteins were further purified, and their N-terminal sequences did not match any protein in current databases. A polyclonal antibody against the fluid 17-kDa protein recognized the protein in the cauda epididymal sperm extract and immunolocalized it on the sperm flagellum membrane and at the luminal border of all cells in the cauda epididymal epithelium. These results indicated that secreted glycoproteins with hydrophobic properties could be directly integrated in a specific domain of the sperm plasma membrane.     

Surface changes in chimpanzee sperm during epididymal transit

Intact chimpanzee caput and cauda epididymal sperm, sperm cell lysates, and caput and cauda epididymal fluid were radiolabeled by enzymatic iodination with lactoperoxidase and Na125 I and were compared by sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis. Caput epididymal sperm showed nine labeled macromolecular components of 90, 64, 56, 48, 38, 31, 20, 18 and 16 Kd and cauda epididymal sperm showed eleven macromolecular components of 90, 64, 55, 47, 42, 33, 27, 18, 17, 15 and 11 Kd. Six of the components labeled on caput sperm (90, 64, 56, 48, 18 and 16 Kd) were detected in equal amounts of cauda sperm and two (38 and 20 Kd) were detected at greatly reduced labeling intensities. In the cauda epididymidis, four new components (33, 27, 17 and 11 Kd) became prominent features of the sperm surface. Analysis of labeled caput and cauda sperm cell lysates resolved components distinct from those detected on sperm surfaces. Electrophoresis of caput epididymal fluid showed five labeled components of 66, 56, 47, 41 and 37 Kd, while electrophoresis of cauda epididymal fluid showed eight labeled components of 92, 66, 56, 48, 31, 27, 24 and 11 Kd. Three components (66, 56 and 47 Kd) were present in both caput and cauda fluid, two (41 and 37 Kd) in caput fluid only, and five (92, 31, 27, 24 and 11 Kd) in cauda fluid only. Components of 37 Kd were labeled in caput fluid and on caput sperm but not on cauda sperm, whereas components of 27 Kd and 11 Kd were labeled in cauda fluid and on cauda sperm but not on caput sperm. These data show that chimpanzee sperm undergo extensive surface modifications during epididymal maturation and that some of these modifications may be related to exogenous proteins/glycoproteins in epididymal fluids.