HEY转录因子的研究进展

Hey属于bHLH(碱性螺旋-环-螺旋)转录因子,具有bHLH和Orange两个结构域.Hey蛋白是Notch信号通路的直接靶基因,在发育决定中起着很重要的作用,例如神经系统、骨骼、骨骼肌、血管、心脏等的发育.研究Hey的发育调控的机制,可以帮助我们更好地理解它们的生物学功能及其在临床诊断和治疗中的重要作用.     

动物胚胎发育讲座（一）：动物胚胎早期发育概况

动物胚胎发育讲座（一）──动物胚胎早期发育概况张天荫（山东大学生物学系济南２５０１００）１生殖细胞与受精生殖细胞的发生在后生动物大致相似,都要经过增殖期、生长期和成熟期。增殖期乃是精（卵）原细胞经过多次有丝分裂使数量不断增加;生长期是部分精（卵）原细...     

巨尾阿丽蝇发育起点及有效积温的研究

巨尾阿丽蝇(Aldrichna granami Aldr)为常见蝇种之一,与人类疾病关系较为密切.在自然温湿条件下研究该蝇发育起点及有效积温常数有助于了解和掌握该蝇年种群的动态规律,为该蝇的预测预报提供理论依据.     

昆虫发育模型研究进展

<正> 昆虫发育模型描述温度对昆虫发育过程的影响。目前,国内外广泛使用的昆虫发育模型归纳起来有3类:(1)发育速率模型;(2)发育时间分布模型;(3)随机发育模型。下面简要介绍各类模型的特点及应用情况。     

糖皮质激素在神经系统发育中的作用

在神经系统的早期发育阶段,糖 皮质激素可通过影响下丘脑－垂体－肾上腺（ＨＰＡ）轴的活动,并经由糖 皮质激素受体介导对神经元和神经胶质的存活、分化、生长和凋亡过程进行调节;在成年阶段,糖皮质激素对与神经元可塑性相关的因子进行调节,从而影响神经元的可塑性变化;在老年阶段,过量的糖皮质激素对神经元更多地产生危害作用。因此,糖皮质激素对神经元的发育起着重要的调节作用。     

蓬莱玉参早期发育的形态学观察

本研究对仿刺参(Apostichopus japonicus)的一个特殊品系蓬莱玉参产卵、受精及胚胎和幼体发育过程进行显微观察,并与普通仿刺参进行比较。在19~21℃水温下,蓬莱玉参受精卵分别在受精12 min和24 min后释放第一、二极体,1 h后卵裂成2细胞期,之后每30 min左右完成一次卵裂,6 h后进入囊胚期,19 h后发育成原肠胚;40 h后进入耳状幼体阶段,在其后侧臂的一端出现一个不规则形的石灰质骨片,并发现其位置与水体腔处于同一侧这一规律;5 d和8 d后发育为中耳状幼体和大耳状幼体,10 d后变态发育为樽形幼体,骨片由不规则状发育为齿轮状,并出现第二个石灰质骨片;12 d后发育为五触手,14 d后发育成稚参,40 d后发育为幼参。蓬莱玉参胚胎和幼体发育时序与当前已报道的仿刺参无显著差异,但从幼参开始蓬莱玉参通体始终为白色,而普通仿刺参在45日龄时体表局部出现色素,疣足处较为明显,60日龄幼体一半以上全身布满色素。蓬莱玉参因通体纯白色而受到了众多养殖企业和研究领域的关注,本文的结果为其今后的研究奠定了可靠的理论基础。     

进化发育生物学--发育、进化和遗传的再联合

发育生物学和进化生物学,以及遗传学历史上曾一度是彼此不分的统一体,后来由于各自研究重点的不同和相应研究手段的独立发展彼此分道扬镳了。如今,由于分子遗传学研究手段的革新使得基因序列测定成为分析发育机理、区分物种和评估种间亲缘关系的常规手段,三者又在基因水平上再度统一起来了,并形成一门被称为进化发育生物学（ｅｖｏｌｕｔｉｏｎａｒｙ ｄｅｖｅｌｏｐｍｅｎｔａｌ ｂｉｏｌｏｇｙ）的新学科。     

山羊（Capra hircus）重构胚与再重构胚早期发育的研究

选择山羊９细胞期到桑椹胚期的正常胚胎或重构胚的卵裂球,或选择胚泡期胚胎的内细胞团细胞作为供核,并以ＬＲＨ注射后２６－２８ｈ的去核成熟卵球作为受体,制备重构胚或再重构胚,琼脂糖包埋,植入山羊输卵管内,体内培养４－６天发育结果表明：不同发育时期（８细胞期至胚泡期）的正常胚胎细胞核或重构胚细胞核中,至少有部分细胞核均保留着发育的全能性;这些细胞核在母系基因表达产物的调控下,实现＝重新编程,启动并完成正常     

m iR NAs 的研究进展

MicroRNAs（miRNAs）是一种大小约21—23个碱基的单链小分子RNA,广泛存在于真核生物中。miRNAs在物种间具有高度的保守性、时序性和组织特异性。miRNAs可以通过部分互补或者完全互补结合到目的靶mRNA,以诱发蛋白质翻译抑制（翻译抑制子）或者介导目的mRNA的降解调节基因表达,参与生命过程中一系列的重要进程,包括细胞分化、生物发育、疾病的发生、发展,此外miRNAs还与病毒的复制和癌症等有关。miRNA作用和功能的揭示必定给nfiRNA的应用带来广阔前景。     

OPGL对骨骼和淋巴发育的作用

OPGL是OPG（osteoprotegrin）的配体。人opgl cDNA编码317个氨基酸的多肽,是一种跨膜蛋白。研究表明OPGL是一种新发现的破骨细胞分化因子。破骨细胞前体在OPGL的作用下,可分化为成熟的破骨细胞。OPGL可激活离体的成熟破内细胞吸收骨质,最新的研究表明,opgl-knockout小鼠出现严重的石骨症,对骨骼再造形具有重要的作用;并且小鼠的胸腺细胞和B淋巴细胞的发育受阻,淋巴结的器官发生也受到抑制,不能形成淋巴结。     

人体测量指标与掌指纹特征之间的相关研究

本文对106名中国东北汉族女性进行了活体测量,并拓取了掌指纹。样本的年龄范围为18—34岁。所分析的人体测量指标共41项,掌指纹指标共59项。将人体测量指标与掌指纹指标同时输入电子计算机,进行了100项实验指标间的相关分析,并做了相关显著性检验。在41项人体测量指标中,有35项指标与掌指纹特征有相关关系。其中与掌指纹特征同时相关的人体测量特征有18项,与指纹特征相关的人体测量指标有2项,与掌纹相关的人体测量指标有15项。与掌指纹特征同时相关的人体测量特征,与遗传因素之间的相互关系大于与指纹相关的人体测量特征。与指纹相关的人体测量特征,与遗传因素的关系,要大于与掌纹相关的人体测量特征。     

Mass, center of mass, and moment of inertia estimates for infant limb segments.

To quantify limb dynamics, accurate estimates are needed of anthropometric inertia parameters (mass, center-of-mass location, and moments of inertia). These estimates, however, are not available for human infants; therefore, the movement dynamics of infants have not been studied extensively. Here, regression equations for the masses, center-of-mass locations, and transverse moments of inertia of upper and lower limb segments (upper arm, forearm, and hand; thigh, leg, and foot) of 0.04 to 1.50 yr old infants are provided. A mathematical model of the human body was used to determine the anthropometric inertia parameters for upper limbs in 44 infants and for lower limbs in 70 infants. Stepwise linear regressions were used to fit the distributions of the anthropometric inertia parameters. The regression equations accounted for significant amounts of the variance (64-98%), and the R2-values compared favorably when our equations were cross-validated. Consequently, these regression equations can provide, for infants of similar ages, reasonable estimates of upper and lower limb anthropometric inertia parameters, suitable for equations of motion in the analysis of limb dynamics in human infants.     

河南新乡地区儿童的体质发育与体型

本文报道了河南省新乡地区４－１３岁汉族儿童的１８项体质指标的测试结果,并计算了８项体质发育指数;分析了本地区儿童生长发育的特点,并与文献资料进行了比较;据有关指数,确定该地区汉族儿童躯干部的体质类型为：长躯干型、窄胸型、窄肩型、窄骨盆型。     

Limb lengths of primary school children in a city from western region of Turkey

Anthropometry has been used for the assessment of growth at different ages. Among the anthropometric measurements, weight, height, arm circumference, and lower and upper limb lengths are of the most important criteria showing the development of children in school age. The aim of the present study was to measure the lengths of upper (arm, forearm, hand) and lower (thigh, leg, foot) limbs of children studying in primary schools of Aydin, a city in the western region of Turkey, and to assess the differences according to the gender (female, male) and living areas (urban, rural). In different age groups, many differences were observed when compared for gender and area. Differences were also seen when compared with the other studies done in different part of Turkey. The data was the first one for the region and it might be useful for further regional studies or for national comparisons. More studies designed with bigger sample sizes that cover many cities belonging to the same region of the country are needed. In addition to cross-sectional studies, longitudinal studies may give more useful knowledge for understanding the growth of children.     

Changes in segmental inertial properties with age

The purpose of this study was to examine how the limb segment inertial parameters vary across the decades from the 1920s to the 1970s. Sixty-six males participated in this study, ranging in age from 20 to 79 years. Pre-screening ensured that all subjects were healthy. The inertial properties of the segments were determined by modeling each segment as series of geometric solids. A multivariate analysis of variance (ANOVA) revealed statistically significant differences between decade age groups for the upper arm, forearm, shank, and thigh (p<0.01). Subsequent ANOVAs revealed statistically significant differences for all the inertial properties for the upper arm, the center of mass location for the forearm, and segment mass for the thigh. Linear regression lines were fit to the data so that each inertial parameter for each segment could be predicted by subject's age, with the slope of this regression line indicating the trend in the data. These trends were statistically significant for all forearm inertial parameters, thigh mass and longitudinal moment of inertia, and forearm center of mass location. The changes for the thigh, upper arm, and forearm were consistent with the changes, which would accompany a change in muscle mass with aging. Resultant joint moments were computed for a set of gait data using inertial properties reflective of the subjects from the age extremes in the study. The resulting differences in the knee and hip moments, young versus old, were all less than 4.5%.     

Validity of estimating limb muscle volume by bioelectrical impedance.

The present study aimed to investigate the validity of estimating muscle volume by bioelectrical impedance analysis. Bioelectrical impedance and series cross-sectional images of the forearm, upper arm, lower leg, and thigh on the right side were determined in 22 healthy young adult men using a specially designed bioelectrical impedance acquisition system and magnetic resonance imaging (MRI) method, respectively. The impedance index (L(2)/Z) for every segment, calculated as the ratio of segment length squared to the impedance, was significantly correlated to the muscle volume measured by MRI, with r = 0.902-0.976 (P < 0.05). In these relationships, the SE of estimation was 38.4 cm(3) for the forearm, 40.9 cm(3) for the upper arm, 107.2 cm(3) for the lower leg, and 362.3 cm(3) for the thigh. Moreover, isometric torque developed in elbow flexion or extension and knee flexion or extension was significantly correlated to the L(2)/Z values of the upper arm and thigh, respectively, with correlation coefficients of 0.770-0.937 (P < 0.05), which differed insignificantly from those (0.799-0.958; P < 0.05) in the corresponding relationships with the muscle volume measured by MRI of elbow flexors or extensors and knee flexors or extensors. Thus the present study indicates that bioelectrical impedance analysis may be useful to predict the muscle volume and to investigate possible relations between muscle size and strength capability in a limited segment of the upper and lower limbs.     

Manual segmentation of DXA scan images results in reliable upper and lower extremity soft and rigid tissue mass estimates

Quantification of segment soft and rigid tissue masses in living people is important for a variety of clinical and biomechanical research applications including wobbling mass modeling. Although Dual-energy X-ray Absorptiometry (DXA) is widely accepted as a valid method for this purpose, the reliability of manual segmentation from DXA scans using custom regions of interest (ROIs) has not been evaluated to date. Upper and lower extremity images of 100 healthy adults who underwent a full body DXA scan in the supine position were manually segmented by 3 measurers independently using custom ROIs. Actual tissue masses (fat mass, lean mass, bone mineral content) of the arm, arm with shoulder, forearm, forearm and hand, thigh, leg, and leg and foot segments were quantified bilaterally from the ROIs. There were significant differences between-measurers, however, percentage errors were relatively small overall (<1–5.98%). Intraclass correlation coefficients (ICCs) were very high between and within-measurers, ranging from 0.990 to 0.999 and 0.990 to 1.00 for the upper and lower extremities, respectively, suggesting excellent reliability. Between and within-measurer errors were comparable in general, and differences between the tissue types were small on average (maximum of 42 and 53 g for upper and lower extremities, respectively). These results suggest that manual segmentation of DXA images using ROIs is a reliable method of estimating soft and rigid tissues in living people.     

Residual Upper Arm Motor Function Primes Innervation of Paretic Forearm Muscles in Chronic Stroke after Brain-Machine Interface (BMI) Training

Background

Abnormal upper arm-forearm muscle synergies after stroke are poorly understood. We investigated whether upper arm function primes paralyzed forearm muscles in chronic stroke patients after Brain-Machine Interface (BMI)-based rehabilitation. Shaping upper arm-forearm muscle synergies may support individualized motor rehabilitation strategies.

Methods

Thirty-two chronic stroke patients with no active finger extensions were randomly assigned to experimental or sham groups and underwent daily BMI training followed by physiotherapy during four weeks. BMI sessions included desynchronization of ipsilesional brain activity and a robotic orthosis to move the paretic limb (experimental group, n = 16). In the sham group (n = 16) orthosis movements were random. Motor function was evaluated with electromyography (EMG) of forearm extensors, and upper arm and hand Fugl-Meyer assessment (FMA) scores. Patients performed distinct upper arm (e.g., shoulder flexion) and hand movements (finger extensions). Forearm EMG activity significantly higher during upper arm movements as compared to finger extensions was considered facilitation of forearm EMG activity. Intraclass correlation coefficient (ICC) was used to test inter-session reliability of facilitation of forearm EMG activity.

Results

Facilitation of forearm EMG activity ICC ranges from 0.52 to 0.83, indicating fair to high reliability before intervention in both limbs. Facilitation of forearm muscles is higher in the paretic as compared to the healthy limb (p<0.001). Upper arm FMA scores predict facilitation of forearm muscles after intervention in both groups (significant correlations ranged from R = 0.752, p = 0.002 to R = 0.779, p = 0.001), but only in the experimental group upper arm FMA scores predict changes in facilitation of forearm muscles after intervention (R = 0.709, p = 0.002; R = 0.827, p<0.001).

Conclusions

Residual upper arm motor function primes recruitment of paralyzed forearm muscles in chronic stroke patients and predicts changes in their recruitment after BMI training. This study suggests that changes in upper arm-forearm synergies contribute to stroke motor recovery, and provides candidacy guidelines for similar BMI-based clinical practice.     

Limb growth in captive Galago senegalensis: getting in shape to be an adult

Since primate infants are not simply miniature adults, adult shape results from differential growth patterns of individual body segments. Initially an infant relies on its mother for transportation, and later begins independent locomotion. Skeletal growth patterns must meet the functional demands of independent locomotion. In this study we sought to determine whether Galago senegalensis braccatus follow the general primate pattern of decreasing intermembral index (IMI) throughout ontogeny. We also asked whether ontogenetic attainment of adult limb proportions coincides with attainment of independent locomotion, i.e., do infants reach adult limb proportions near the time they begin independent locomotion (approximately 7 weeks of age)? Mixed‐longitudinal data were taken from a sample of 10 captive‐born Galago senegalensis. Linear lengths of the trunk, arm, forearm, thigh, and leg were measured in the animals from birth until they were approximately 500 days old. The IMI and the ratio of each limb segment to both trunk length and the cube root of body mass were calculated. The results of a Mann‐Whitney Wilcoxon rank‐sum test for unmatched samples indicate that G. senegalensis do exhibit the primate pattern of decreasing IMI throughout ontogeny, and that the IMIs of infants at the time of initial locomotor independence are significantly higher than those of adult IMIs. Some (but not all) measures of relative limb lengths differed between neonates or 7‐week‐old infants and adults. Therefore, the hypothesis that infants acquire adult limb proportions by the time they begin independent locomotion is not supported by this study. The current results indicate that ontogenetic shape changes in galagos are a complex process and apparently cannot be explained by simple initial locomotor competency. Am. J. Primatol. 69:103–111, 2007. © 2006 Wiley‐Liss, Inc.     

Comparative postcranial body shape and locomotion in Chlorocebus aethiops and Cercopithecus mitis

Body weight and length, chest girth, and seven postcranial limb segment lengths are compared between two guenon species, Chlorocebus (Cercopithecus) aethiops (vervets) and Cercopithecus mitis (blue monkeys), exhibiting different habitual locomotor preferences. The subjects, all adults, were wild caught for a non-related research project (Turner et al. [1986] Genetic and morphological studies on two species of Kenyan monkeys, C. aethiops and C. mitis. In: Else JG, Lee PC, editors. Primate evolution, proceedings of the Xth International Congress of Primatology, Cambridge. London). The morphological results are interpreted within the context of previously published observations of primate locomotion and social organization. The sample is unique in that the body weight of each individual is known, allowing the effects of body-size scaling to be assessed in interspecific and intersexual comparisons. C. mitis has a significantly (P < 0.05) greater body weight and trunk length than C. aethiops. A shorter trunk may function to reduce spinal flexibility for ground-running in the latter. Proximal limb segments (arm and thigh) are significantly greater in C. mitis, reflecting known adaptations to committed arboreal quadrupedal locomotion. By contrast, relative distal limb segments (forearm, crus, and foot) are significantly longer in C. aethiops, concordant with a locomotor repertoire that includes substantial terrestrial quadrupedalism, in addition to arboreal agility, and also the requisite transition between ground and canopy. Although normally associated with arboreal monkeys, greater relative tail length occurs in the more terrestrial vervets. However, because vervets exploit both arboreal and terrestrial habitats, a longer tail may compensate for diminished balance during arboreal quadrupedalism resulting from the greater "brachial" and "crural" indices that enhance their ground quadrupedalism. Most interspecific differences in body proportions are explicable by differences in locomotor modalities. Some results, however, contradict commonly held "tenets" that relate body size and morphology exclusively to locomotion. Generally associated with terrestriality, sexual dimorphism (male/female) is greater in the more arboreal blue monkeys. A more intense, seasonal mating competition may account for this incongruity.