恒河猴血清前白蛋白和抗凝血酶 Ⅲ火箭免疫电泳测定研究

本文应用火箭免疫电泳法测定了67只正常恒河猴血清中的前白蛋白和42只血清中抗凝血酶Ⅲ的参考值。 前白蛋白由肝脏合成能与甲状腺素及维生素A结合,与肝胆疾病有密切关系。抗凝血酶Ⅲ是生理性抗凝系统的主要成分。均在临床上被广泛应用。为了实验工作的需要,我们测定了恒河猴的这2项指标都比人类高,其原因可能与饲养条件、环境、营养等有关。     

四个不同种属动物肢体Ⅱ导联心电图比较

目的对比格犬、恒河猴、日本大耳白兔、树鼩四个不同种属实验动物的ECG-II进行分析比较,归纳其ECG-II的特点,旨在为上述动物在安评中的运用提供参考。方法选择成年比格犬、恒河猴、日本大耳白和树鼩,分别对其在清醒状态下的ECG-II进行描记和分析,并对ECG-II各项指标进行测量分析。结果与结论不同种属动物均为窦性心律,在波型方面基本一致,未出现特异性改变,但不同动物在QRS波群和T波形态上具有一定差异;各指标测定结果显示,日本大耳白兔P波、T波振幅和树鼩心率分别小于和快于其他种属动物。     

UFLC-MS/MS研究胡椒碱在不同种属肝微粒体中的代谢稳定性和代谢表型

应用体外肝微粒体孵育体系,考察胡椒碱在人、SD大鼠、小鼠、恒河猴和比格犬5个种属肝微粒体中的代谢稳定性,比较代谢的种属差异,确定其在人肝微粒体中的代谢表型。通过UFLC-MS/MS检测方法,测定胡椒碱在各个种属肝微粒体中孵育后的剩余浓度,考察他们的代谢稳定性及体外代谢动力学参数。采用化学抑制法考察胡椒碱在人肝微粒体中的代谢表型。结果表明胡椒碱在人、SD大鼠、小鼠、恒河猴和比格犬的肝微粒体中,半衰期T1/2分别为31. 36、48. 46、138. 60、147. 45、165. 00 min;体外固有清除率CLint分别为0. 0442、0. 0286、0. 0100、0. 0094、0. 0084m L/(m L·mg);在人肝微粒体中,胡椒碱主要被CYP3A4和CYP2C9酶代谢。推测胡椒碱在各种肝微粒体中的代谢均相对较稳定,其中大鼠和人的肝微粒体代谢性质最相近,在后续的实验中可以考虑用大鼠的代谢结果预测人的代谢结果;人肝微粒体中参与胡椒碱代谢的酶主要有CYP3A4和CYP2C9。     

小鼠抗食蟹猴IgG单克隆抗体的制备

目的制备抗食蟹猴、恒河猴等非人灵长类实验动物免疫球蛋白二级抗体,开展对其传染病血清学快速诊断方法的建立。方法采用饱和硫酸铵盐析、Agarose-Protein G亲和层析技术,从食蟹猴血清中提纯IgG。经SDS-PAGE电泳鉴定,采用常规法免疫C57BL/6小鼠,三次免疫后取脾细胞与Sp2/0-Ag14骨髓瘤细胞通过PEG4000融合制备杂交瘤细胞,利用间接ELISA、Western blot等方法进行筛选、鉴定。结果得到5株阳性杂交瘤,分别命名为2B6、2B7、2D9、3B2、5E4,并且5株杂交瘤分泌的抗体均与恒河猴的IgG或血清发生交叉反应,而与其他物种如东北虎、犬等动物的IgG或血清无交叉反应。结论 5株杂交瘤产生的单克隆抗体（McAb）具有较好免疫活性,且能长期、稳定地分泌抗体。此项研究工作为后续研究食蟹猴、恒河猴传染病血清学诊断方法奠定基础。     

GDF5基因真核表达载体的构建及其在恒河猴骨髓间充质干细胞中的表达

目的克隆人软骨组织生长分化因子5（GDF5）基因及构建GDF5基因真核表达载体,观察其在恒河猴骨髓间充质干细胞（MSCs）中的表达情况。方法采用反转录聚合酶链式反应（RT-PCR）从人胎儿软骨组织克隆hGDF5基因全长cDNA,插入pEGFP-C2载体,构建重组真核表达质粒pEGFP-C2-GDF5。重组质粒脂质体介导法转染MSCs细胞,荧光显微镜观察报告基因的表达,RT-PCR法检测目的基因表达。结果成功克隆人软骨组织GDF5基因和构建GDF5真核表达质粒pEGFP-C2-GDF5,克隆在载体上的基因长度为1505bp,包含全部cDNA编码序列1505bp,测序显示与Genbank上的序列一致。重组质粒转染恒河猴MSCs细胞得到表达,绿色荧光蛋白在转染24h后开始表达,72h达高峰,然后表达逐渐减弱。转染后72h可检测到GDF5mRNA表达。结论人GDF5基因在恒河猴MSCs细胞的成功表达为应用恒河猴模型开展基于细胞的基因疗法修复骨和软骨损伤研究奠定了必要基础。     

杆状病毒转导不同哺乳动物骨髓来源间充质干细胞

杆状病毒作为一种新型基因载体,若能有效转导不同哺乳动物骨髓来源间充质干细胞(bone marrow-derived mesenchymal stem cells, BMSCs),将会成为干细胞基因修饰研究领域中更理想的一种基因载体.本文探讨了重组杆状病毒(BacV-CMV-EGFP)对不同哺乳动物BMSCs的转导效率.体外原代培养小鼠、大鼠、猪、恒河猴及人的BMSCs.用培养3代以上的哺乳动物BMSCs进行病毒转导实验,转导2d后用倒置荧光显微镜观察绿色荧光蛋白在不同哺乳动物BMSCs中的表达,并用流式细胞仪检测重组杆状病毒对不同哺乳动物BMSCs的转导效率.结果显示:原代培养的小鼠、大鼠、猪、恒河猴及人的BMSCs于体外传代3次以上后,细胞呈现较均一的梭形,漩涡状生长;倒置荧光显微镜观察显示,与小鼠、大鼠、猪的BMSCs相比,恒河猴及人有更多BMSCs表达绿色荧光蛋白,且荧光强度较强;杆状病毒对小鼠、大鼠、猪、恒河猴及人的BMSCs的转导效率分别为(21.21±3.02)%、(22.51±4.48)%、(39.13±5.79)%、(71.16±5.36)%及(70.67±3.74)%.上述结果表明,重组杆状病毒对不同哺乳动物BMSCs的转导效率不同,对恒河猴及人的BMSCs转导效率较高,说明重组杆状病毒可作为人或灵长类动物BMSCs基因修饰研究领域中更理想的基因载体.     

全身一体化成像技术在恒河猴动物实验中的应用

目的探讨并比较CT与核磁共振成像（magnetic resonance imaging,MRI）在恒河猴全身成像研究中的应用范围,以及全身一体化技术（total imaging Matrix,TIM）配合增强扫描对恒河猴骨骼、循环、神经系统成像,总结其影像学表现中与人相应系统解剖的差异。方法应用64层螺旋CT的表面遮盖成像重建技术（3D-SSD）对恒河猴全身骨骼系统进行全身平扫及重建,3．0TMRI的TIM技术与最大密度投影重建（MIP）对恒河猴循环系统、神经系统进行全身平扫及增强扫描并重建。结果64层螺旋CT骨骼系统成像显示恒河猴腰椎骨6块、骶椎骨8块、尾椎骨11块、真肋骨9根,数量多于人类;颈椎棘突未见分叉,与人类不同。MRI动态增强技术与一体化成像技术联用显示恒河猴的动脉系统与人类相近,端脑矢状位最长径与冠状位最长径比值比人类略低,脊髓膨大位置比人类略低。结论多层螺旋CT与MRI的TIM技术可应用于对大型实验动物进行无创性的解剖学分析,是一种无创、快速、可以在体研究并动态连续观察其结构的科学有效方法。     

实时荧光定量检测中国实验用小型猪肝脏CYP3A29 mRNA表达水平

CYP3A29是猪肝脏最重要的药物代谢关键酶。研究中国实验用小型猪肝脏CYP3A29 mRNA的表达特性对于评估其是否适宜于作为人CYP3A4介导的药理学研究动物模型具有一定意义。以b-actin作校正, 利用TaqMan定量技术对巴马香猪、贵州小型香猪肝脏CYP3A29 mRNA表达水平进行检测, 并以荣昌猪作为对照。结果表明, 巴马香猪、贵州小型香猪、荣昌猪肝脏CYP3A29 mRNA表达水平与报道的人肝脏CYP3A4相近; 三品系(种)猪间肝脏CYP3A29 mRNA表达水平较为接近, 但品系(种)内个体间变异较大。提示巴马香猪、贵州小型香猪作为药物评价的实验动物具有一定可行性。     

灵长类动物的基因定向修饰——记运用CRISPR/Cas9技术获得基因定向敲除食蟹猴

早在2001年1月,美国科学家在Science上报道了世界上第一只转基因恒河猴,他们利用慢病毒转染法成功地将绿色荧光蛋白(GFP)转入恒河猴早期胚胎,并通过胚胎移植获得了GFP整合和表达的转基因猴ANDi,这是转基因技术在非人灵长类上的首次成功尝试。2008年,Shang-Hsun Yang等人成功构建出了亨廷顿疾病(HD)的转基因恒河猴模型,作者将84个CAG重复序列连接到人HTT基因第一个外显子上,并将其包装成高滴度的慢病毒粒子(滴度109 PFU/mL)后,在卵母细胞带下注射病毒后再进行单精注射受精和胚胎移植,成功得到了第一个转基因非人灵长类疾病模型。然而,通过慢病毒介导的方式产生的转基因动物,外源基因的随机插入使得它的表达和功能的实现具有一定的不确定性。在灵长类动物中,由于技术限制无法通过与大小鼠同样的技术路线获得精确基因修饰的动物。以TANLENs、CRISPR/Cas9技术为代表的人工核酸酶介导的基因组编辑技术的诞生,使得在灵长类动物中实现精确基因修饰成为可能。季维智研究员团队与南京医科大学沙家豪教授和南京大学黄行许教授团队密切合作,成功运用Crispr/Cas9技术获得了世界上首例基因定向敲除食蟹猴,证实了CRISPR/Cas9系统可以在灵长类动物中很好地工作,并产生活体动物。这为灵长类疾病动物模型的发展奠定了良好的基础。     

逃避CD8~+T细胞反应是巨细胞病毒重复感染的关键

虽然宿主有针对巨细胞病毒(CMV)的特异性体液和细胞免疫,但它能重复感染已感染的宿主,具体机制还不清楚。该研究证明,CMV需要逃避CD8+T细胞的免疫反应才能重复感染已感染过CMV的恒河猴,这种逃逸是通过病毒编码的主要组织相容性复合物(MHC)I类抗原呈递的抑制剂(特别是与人同源的CMV US2、3、6和11)实现的。相反,干扰MHC-I对初次感染恒河猴及在瞬时去除CD8+T细胞已感染     

Vertebrae numbers of the early hominid lumbar spine

General doctrine holds that early hominids possessed a long lumbar spine with six segments. This is mainly based on Robinson's (1972) interpretation of a single partial Australopithecus africanus skeleton, Sts 14, from Sterkfontein, South Africa. As its sixth last presacral vertebra exhibits both thoracic and lumbar characteristics, current definitions of lumbar vertebrae and lumbar ribs are discussed in the present study. A re-analysis of its entire preserved vertebral column and comparison with Stw 431, another partial A. africanus skeleton from Sterkfontein, and the Homo erectus skeleton KNM-WT 15000 from Nariokotome, Kenya, did not provide strong evidence for the presence of six lumbar vertebrae in either of these early hominids. Thus, in Sts 14 the sixth last presacral vertebra has on one side a movable rib. In Stw 431, the corresponding vertebra shows indications for a rib facet. In KNM-WT, 15000 the same element is very fragmentary, but the neighbouring vertebrae do not support the view that it is L1. Although in all three fossils the transitional vertebra at which the articular facets change orientation seems to be at Th11, this is equal to a large percentage of modern humans. Indeed, a modal number of five lumbar vertebrae, as in modern humans, is more compatible with evolutionary principles. For example, six lumbar vertebrae would require repetitive shortening and lengthening not only of the lumbar, but also of the entire precaudal spine. Furthermore, six lumbar vertebrae are claimed to be biomechanically advantageous for early hominid bipedalism, yet an explanation is lacking as to why the lumbar region should have shortened in later humans. All this raises doubts about previous conclusions for the presence of six lumbar vertebrae in early hominids. The most parsimonious explanation is that they did not differ from modern humans in the segmentation of the vertebral column.     

Analysis of the shoulder in brachiating spider monkeys.

Adult spider monkeys (Ateles geoffroyi and A. paniscus) were conditioned to brachiate on a rope mill (an arboreal analogue of a treadmill). The postures and excursions of the shoulder girdle were studied by cineradiography. These data, together with conventional cinematographic and anatomical studies, permit reassessment of some characteristic structural and functional features of the shoulder in brachiators. During the propulsive phase, the shoulder joint moves caudad from fifth cervical to seventh cervical levels; at the same time, the joint moves dorsad (from a frontal plane midway between the first thoracic vertebra and the manubrium, to a frontal plane through the spinous processes) and slightly mediad. Spider monkeys position the scapula principally on the dorsum of the thorax, in contrast to quadrupedal primates which maintain a more lateral position (even in suspended postures). During brachiation, the scapula rotates a total of 35°; most of this rotation (20°) occurs in the non-propulsive phase when the free arm is being elevated to secure a new handhold. The sigmoidal shape, twisting of proximal relative to distal ends, and elongation of the clavicle in spider monkeys and other brachiators appear to be related to the specialized positioning of the shoulder girdle on the dorsum of the thorax. Shoulder and elbow movements contribute to the efficiency of the swing in terms of the dynamics of a pendulum.     

Ontogenesis of the scapula in marsupial mammals, with special emphasis on perinatal stages of didelphids and remarks on the origin of the therian scapula

The development of the scapula was studied in embryonic and postnatal specimens of Monodelphis domestica and perinatal specimens of Philander opossum, Caluromys philander, and Sminthopsis virginiae using histological sections and 3D reconstructions. Additionally, macerated skeletons of postnatal M. domestica were examined. This study focused on the detachment of the scapulocoracoid from the sternum and on the acquisition of a supraspinous fossa, a supraspinatus muscle, and a scapular spine, all these events associated with the origin of the therian shoulder girdle. In none of the specimens is there a continuity of the cartilaginous scapulocoracoid with the sternum, even though the structures are in close proximity, especially in S. virginiae. At birth, the first rib laterally presents a pronounced boss that probably contacts the humerus during certain movements. Only the acromial portion of the scapular spine, which originates from the anterior margin of the scapular blade, is preformed in cartilage. The other portion is formed by appositional bone ("Zuwachsknochen"), which expands from the perichondral ossification of the scapula into an intermuscular aponeurosis between the supra- and infraspinous muscles. This intermuscular aponeurosis inserts more or less in the middle of the lateral surface of the developing scapula. Thus, the floor of the supraspinous fossa is present from the beginning of scapular development, simultaneously with the infraspinous fossa. The homology of the therian spine with the anterior border of the sauropsid and monotreme scapula is questioned. We consider the dorsal portion (as opposed to the ventral or acromial portion) of the scapular spine a neomorphic structure of therian mammals.     

On the kinematic modelling and the parameter estimation of the human shoulder.

This paper presents some results on the modelling and the corresponding parameter estimation of the human shoulder. This system consists of the clavicle, the scapula, the humerus and the various joints between these bodies and the trunk through the sternum; it will be represented as a succession of a rotational joint between the sternum and the clavicle and a constant distance joint, representing the scapula between, the clavicle and the humerus head. The parameters of this system are the components of the position vectors of the joint characteristic points (the corresponding centres of the rotations). Experimental results are presented as well as a validation of the proposed model.     

Growth of the pectoral girdle of the Leopard frog, Rana pipiens (Anura: Ranidae)

This article describes the growth of the anuran pectoral girdle of Rana pipiens and compares skeletal development of the shoulder to that of long bones. The pectoral girdle chondrifies as two halves, each adjacent to a developing humerus. In each, the scapula and coracoid form as single foci of condensed chondrocytes that fuse, creating a cartilaginous glenoid bridge articulating with the humerus. Based on histological sections, both the dermal clavicle and cleithrum begin to ossify at approximately the same time as the periosteum forms around the endochondral bones. The dermal and endochondral bones of the girdle form immobile joints with neighboring girdle elements; however, the cellular organization and growth pattern of the scapula and coracoid closely resemble those of a long bone. Similar to a long bone epiphysis, distal margins of both endochondral elements have zones of hyaline, stratified, and hypertrophic cartilages. As a result, fused elements of the girdle can grow without altering the glenoid articulation with the humerus. Comparisons of anuran long bone and pectoral girdle growth suggest that different bones can have similar histology and development regardless of adult morphology.     

Sphingosine 1-phosphate differentially regulates proliferation of C2C12 reserve cells and myoblasts

Scoliosis is a condition that involves an abnormal curvature and deformity of the spinal vertebrae. The genetic background and key gene for congenital scoliosis in humans are still poorly understood. Ishibashi rats (ISR) have congenital malformation of the lumbar vertebrae leading to kyphoscoliosis similar to that seen in humans. To understand the pathogenesis of congenital scoliosis, we have studied the abnormality of vertebral formation and the associated gene expression in ISR. Almost all ISR showed kyphosis or scoliosis of the lumbar vertebrae. In ISR with severe kyphosis, some vertebral disks were missing and some vertebral bodies were fused. Of the ISR, 27% showed hemi-lumbarization of lumbar and sacral vertebrae. Homeotic transformation of the first sacral vertebra into the seventh lumbar vertebra and the resultant loss of the fourth sacral vertebra were seen in half of the ISR. We also found unilateral fusions and deformities of primary ossification centers of the lumbar vertebral column in fetal ISR. Moreover, we observed that the expression levels of Hox10 and Hox11 paralogs in lumbo-sacral transitional areas of ISR were extremely low compared with those of normal rats. These results suggest that fusion of primary ossification centers in lumbar vertebrae in the embryonic period causes scoliosis and kyphosis and that Hox genes are involved in the occurrence of homeotic transformation in lumbo-sacral vertebrae of congenital kyphoscoliotic ISR.     

In-vivo analysis of sternal angle,sternal and sternocostal kinematics in supine humans during breathing

This paper aims at contributing to the understanding of the combination of in vivo sternum displacement, sternal angle variations and sternocostal joints (SCJ) kinematics of the seven first rib pairs over the inspiratory capacity (IC). Retrospective codified spiral-CT data obtained at total lung capacity (TLC), middle of inspiratory capacity (MIC) and at functional residual capacity (FRC) were used to compute kinematic parameters of the bones and joints of interest in a sample of 12 asymptomatic subjects. 3D models of rib, thoracic vertebra, manubrium and sternum were processed to determine anatomical landmarks (ALs) on each bone. These ALs were used to create local coordinate system and compute spatial transformation of ribs and manubrium relative to sternum, and sternum relative to thoracic vertebra. The rib angular displacements and associated orientation of rotation axes and joint pivot points (JPP), the sternal angle variations and the associated displacement of the sternum relative to vertebra were computed between each breathing pose at the three lung volumes. Results can be summarized as following: (1) sternum cephalic displacement ranged between 17.8 and 19.2 mm over the IC; (2) the sternal angle showed a mean variation of 4.4° ± 2.7° over the IC; (3) ranges of rib rotation relative to sternum decreased gradually with increasing rib level; (4) axes of rotation were similarly oriented at each SCJ; (5) JPP spatial displacements showed less variations at first SCJ compared to levels underneath; (6) linear relation was demonstrated between SCJ ROMs and sternum cephalic displacement over the IC.     

The kinematics of the scapulae and spine during a lifting task

Simultaneous motion of the scapula and humerus is widely accepted as a feature of normal upper limb movement, however this has usually been investigated under conditions in which purposeful, functional tasks were not considered. The aim of this study was to investigate the synchrony and coordination of the constituent 3D movements of the shoulder girdle and trunk, during a functional activity. 45 healthy women, aged between 20 and 80 years, performed a simple lifting task, moving a loaded box from a shelf at waist level to one at shoulder level and then reversed the movement, during which the linear and angular motions of the scapulae, upper and lower thoracic spine and upper limbs were monitored and analysed using cross-correlation techniques. Results indicated a close and consistent set of coordinated movement patterns, which suggest biomechanical invariance in the responses of the structures adjacent to the upper limb during such a lifting task. These scapulohumeral relationships were, however, more constant and phase-locked when there was a specific purpose to the movement than during periods in which the arm was lowered without load. There were no age-related differences in any movement responses.