隐睾小鼠与正常成年小鼠睾丸蛋白表达谱的差异分析

为使精原干细胞（spermatogonial stem cells,SSCs）在体外大量扩增,需要阐明SSCs自增殖机制。为筛选SSCs自增殖相关因子,探索SSCs自增殖机制,本研究选取10日龄昆明乳鼠行隐睾手术,术后35d分别取小鼠两侧睾丸。组织学分析结果显示,实验性隐睾中生殖细胞的分化停滞在精母细胞阶段,且只有少量的精母细胞出现,精原细胞的比例高于正常成年雄性小鼠（45日龄）。应用双向凝胶电泳分析隐睾小鼠与正常成年小鼠睾丸差异表达蛋白。结果显示,与正常成年小鼠相比,隐睾小鼠睾丸中有9种蛋白表达发生了显著变化,其中6种蛋白表达下调,3种上调。对9种差异表达蛋白点胶内酶切后进行质谱分析,其中4种蛋白分别鉴定为磷脂酰乙醇胺结合蛋白1（phosphatidylethanolamine-binding protein1,PEBP1）,HES—related basic helix-100p-helix protein（HERP）,Stathmin蛋白和一种未命名蛋白。本研究通过制作有效的隐睾动物模型,运用蛋白组学的技术方法,成功筛选并鉴定了4种隐睾相关蛋白,有助于探讨SSCs自增殖及隐睾引起雄性不育的机制。     

Clycerolphosphate oxidase and succinate dehydrogenase activities in IIA and IIB fibres of mouse and rabbit tibialis anterior muscles

Summary Quantitative microphotometric measurements of two mitochondrial flavoproteins, glycerolphosphate oxidase (GP-OX) and succinate dehydrogenase (SDH), were performed on serial sections of mouse and rabbit tibialis anterior (TA) muscles in order to study the distribution of these two enzymes and their activity ratios in IIA and IIB fibres. The measurements showed a large scatter of the two enzyme activities in these two myosin-based fibre types. In rabbit TA, IIA and IIB fibres have similar GP-OX activities, whereas generally IIA fibres have higher SDH activities than IIB fibres. An inverse distribution of the two enzymes exists in mouse muscle. Generally, IIA fibres of mouse TA display low SDH and IIB fibres high SDH activities. The mean activity of GP-OX is slightly higher in IIA than in IIB fibres of mouse TA. Since measurements of both enzymes were taken in the same fibres, the ratio of their activities in each fibre could be evaluated. The SDH/ GP-OX activity ratios vary significantly between the two fibre populations both in rabbit and in mouse. The ratio is high in IIA and low in IIB fibres of rabbit TA, whereas it is low in IIA and high in IIB fibres of mouse TA.     

Glycerolphosphate oxidase and succinate dehydrogenase activities in IIA and IIB fibres of mouse and rabbit tibialis anterior muscles

Quantitative microphotometric measurements of two mitochondrial flavoproteins, glycerolphosphate oxidase (GP-OX) and succinate dehydrogenase (SDH), were performed on serial sections of mouse and rabbit tibialis anterior (TA) muscles in order to study the distribution of these two enzymes and their activity ratios in IIA and IIB fibres. The measurements showed a large scatter of the two enzyme activities in these two myosin-based fibre types. In rabbit TA, IIA and IIB fibres have similar GP-OX activities, whereas generally IIA fibres have higher SDH activities than IIB fibres. An inverse distribution of the two enzymes exists in mouse muscle. Generally, IIA fibres of mouse TA display low SDH and IIB fibres high SDH activities. The mean activity of GP-OX is slightly higher in IIA than in IIB fibres of mouse TA. Since measurements of both enzymes were taken in the same fibres, the ratio of their activities in each fibre could be evaluated. The SDH/GP-OX activity ratios vary significantly between the two fibre populations both in rabbit and in mouse. The ratio is high in IIA and low in IIB fibres of rabbit TA, whereas it is low in IIA and high in IIB fibres of mouse TA.     

Functional characteristics of rat gastrocnemius and tibialis anterior muscles during growth

Several morphological and functional characteristics of the rat gastrocnemius medialis and tibialis anterior muscle were studied in young, adult, and old rats to assess the influence of growth. Antagonist muscles were studied to determine how changes of muscle architecture and functional characteristics are influenced by the demands of increased body weight and by the specific roles of these muscles in locomotion. Both muscles change drastically, for instance, in muscle length, volume, physiological cross-sectional area aponeurosis length, and their muscular geometry changes allometrically for both muscles. The relationships between muscle length, distance between origin and insertion, tendon length, and tibial length also change with growth. Both muscles are rather pennate, so that the increase of physiological cross-sectional area is a major factor in the determination of muscle length. No significant difference could be shown for fundamental physiological characteristics (i.e., functional characteristics normalized for muscular dimensions such as maximal work per unit volume). The changes of morphological and functional variables of both muscles parallel each other as is apparent from the index of antagonist characteristics, which is constant for all variables studied with the exception of muscle volume and tendon length. Consequently, the considerable and similar changes of TA and GM morphology and functional characteristics that take place during growth from approximately four weeks postnatally is not caused by changes of muscular material but by changes of the amount and architectural arrangement of the material involved.     

Differential expression of two clusters of mouse histone genes

The mouse histone mRNAs coded for by three different cloned DNA fragments have been characterized. Two of these cloned DNA fragments, MM221 and MM291, located on chromosome 13, code for H3, H2b and H2a histone mRNAs, which are expressed at low levels in cultured mouse cells and fetal mice. The other DNA fragment, MM614, located on chromosome 3, codes for an H3 and an H2a mRNA, which are expressed at high levels in these cells. The mRNAs for each histone protein share common coding region sequences, while the untranslated regions of all the genes have diverged significantly, as judged by S1 nuclease mapping. Amino acid substitutions in some H3, H2a and H2b proteins are detected as internal cleavages in the S1 nuclease maps. All of these genes code for replication variant histone mRNAs, which are regulated in parallel with DNA synthesis.     

High-energy phosphates and tension production in rabbit tibialis anterior/extensor digitorum longus muscles

Ryschon, T. W., J. C. Jarvis, S. Salmons, and R. S. Balaban.High-energy phosphates and tension production in rabbit tibialisanterior/extensor digitorum longus muscles. J. Appl. Physiol. 82(3): 1024-1029, 1997.The effects ofrepetitive muscle contraction on energy state and tension productionwere studied in rabbit tibialis anterior/extensor digitorum longusmuscles that had been subjected to 90 days of continuous indirectelectrical stimulation at 10 Hz. Anesthetized chronically stimulatedand control rabbits were challenged with 15 min of stimulation at 4 and15 tetani/min.P_i-to-phosphocreatine (PCr) ratio(P_i/PCr) was measured in vivo before, during, andafter acute stimulation by³¹P-magnetic resonancespectroscopy, and tension was recorded at the same time. AlthoughP_i/PCr was low at rest, it wassignificantly higher in chronically stimulated muscle than in controlmuscle (0.20 ± 0.02 vs. 0.05 ± 0.01, P < 0.05). Stimulation of control muscle for 15 min at both 4 and 15 tetani/min induced a significant rise in P_i/PCr, whereas the sameconditions in chronically stimulated muscle did not produce anysignificant departure from initial levels. The tension produced bycontrol muscle fell to 93 ± 3% of its initial value duringstimulation at 4 tetani/min and to 61 ± 7% at 15 tetani/min,respectively. In chronically stimulated muscle, on the other hand,tension was potentiated above its initial level at both stimulationrates (135 ± 15 and 138 ± 11%, respectively) and remainedsignificantly elevated throughout each trial. The ability ofchronically stimulated muscle to sustain high levels of activity withminimal perturbations in P_i/PCr ordecrement in tension is attributable to cellular adaptations thatinclude a well-documented increase in oxidative capacity.

     

Contraction level-related modulation of corticomuscular coherence differs between the tibialis anterior and soleus muscles in humans

The sensorimotor cortex activity measured by scalp EEG shows coherence with electromyogram (EMG) activity within the 15- to 35-Hz frequency band (β-band) during weak to moderate intensity of isometric voluntary contraction. This coupling is known to change its frequency band to the 35- to 60-Hz band (γ-band) during strong contraction. This study aimed to examine whether such contraction level-related modulation of corticomuscular coupling differs between muscles with different muscle compositions and functions. In 11 healthy young adults, we quantified the coherence between EEG over the sensorimotor cortex and rectified EMG during tonic isometric voluntary contraction at 10-70% of maximal voluntary contraction of the tibialis anterior (TA) and soleus (SOL) muscles, respectively. In the TA, the EEG-EMG coherence shifted from the β-band to the γ-band with increasing contraction level. Indeed, the magnitude of β-band EEG-EMG coherence was significantly decreased, whereas that of γ-band coherence was significantly increased, when the contraction level was above 60% of maximal voluntary contraction. In contrast to the TA, the SOL showed no such frequency changes of EEG-EMG coherence with alterations in the contraction levels. In other words, the maximal peak of EEG-EMG coherence in the SOL existed within the β-band, irrespective of the contraction levels. These findings suggest that the central nervous system regulates the frequency of corticomuscular coupling to exert the desired levels of muscle force and, notably, that the applicable rhythmicity of the coupling for performing strong contractions differs between muscles, depending on the physiological muscle compositions and functions of the contracting muscle.     

Comparison of force and EMG measures in normal and reinnervated tibialis anterior muscles of the rat.

The relationship between motor unit force and the recorded voltage produced by activated muscle unit fibres (electromyogram, EMG) was examined in normal and reinnervated rat tibialis anterior muscles. The number, cross-sectional area, and radial distance from the recording electrode of muscle fibres in a given unit, obtained directly from a sample of glycogen-depleted motor units, were analysed in relation to the magnitude of the EMG signal produced by that unit. EMG peak to peak amplitude and area varied as approximately the square root of twitch force in both normal and reinnervated units. Furthermore, the EMG amplitude increased approximately as the total cross-sectional area of the motor unit (number of muscle fibres x the average cross-sectional area of the fibres) and inversely with approximately the square root of the distance of fibres from the recording electrodes on the surface of the muscle.     

Telemetry system to record force and EMG from cat ankle extensor and tibialis anterior muscles

The purpose of this technical note is to present the design of an eight-channel telemetry system of dimensions and weight small enough to record muscular forces and EMGs simultaneously from gastrocnemius, soleus, plantaris and tibialis anterior muscles of a freely moving cat. All schematics for constructing the telemetry device are shown in detail. Using this system, we were successful in measuring force and EMG data of all four instrumented muscles in freely moving animals. The telemetry system presented here has the advantage over a conventional cable system that recordings may be obtained at any time in the freely moving animal without interference by an experimenter.     

Intramuscular pressure, force and blood flow in rabbit tibialis anterior muscles during single and repetitive contractions

The elevated intramuscular pressure (IMP) associated with sustained muscle contraction can affect blood flow, and could influence the long-term viability of functional skeletal muscle grafts. We therefore examined the relationship between force, peak IMP and blood flow in the tibialis anterior muscle of the anaesthetized rabbit. During isometric contractions, IMP was related linearly to force, and only the slope of the relationship varied between animals. During isotonic contractions, however, the highest values of IMP were found at the lowest force levels, and IMP appeared to be related to the amount and speed of shortening. During repeated isometric contractions, the ratio of IMP to force varied with time, stimulation pattern and subject. Mean blood flow did not differ appreciably between␣repetitive isometric contractions at duty cycles of 10–40%, and was unrelated to integrated pressure, integrated force, or depth from the surface. We conclude: (1) that IMP is unlikely to affect mean blood flow during cyclic activity that has a duty cycle less than 40%; and (2) that the clinical use of IMP as a predictor of muscle force appears to be justified only for single isometric contractions, and needs to be interpreted cautiously when contractions involve shortening or fatigue. Accepted: 17 November 1997     

Activation timing of soleus and tibialis anterior muscles during sit-to-stand and stand-to-sit in post-stroke vs. healthy subjects

Introduction. Sit-to-stand (SitTS) and stand-to-sit (StandTS) are very important functional tasks that become compromised in stroke patients. As in other voluntary movements, they require an adequate postural control (PC) involving the generation of anticipatory postural adjustments (APAs). In order to give clues for more efficient and directed rehabilitation programs, a deeper knowledge about APAs during challenging and daily life movements is essential.

Purpose. To analyze the activation timing of tibialis anterior (TA) and soleus (SOL) muscles during SitTS and StandTS in healthy subjects and in post-stroke patients.

Methods. Two groups participated in this study: one composed of ten healthy subjects and the other by ten subjects with a history of stroke and increased H-reflex. Electromyographic activity (EMGa) of SOL and TA was analyzed during SitTS and StandTS in the ipsilateral (IPSI) and the contralateral (CONTRA) limb to the side lesion in stroke subjects, and in one limb in healthy subjects. A force plate was used to identify the movement onset.

Results. In both sequences, in the stroke group SOL activation timing occurred prior to movement onset, contrary to the pattern observed in the healthy subjects. Statistically significant differences were found in SOL activation timings between each lower limb of the stroke and healthy groups, but no significant differences were found between the IPSI and the CONTRA limb. The TA activation timing seems to be delayed in the CONTRA limb when compared to the healthy subjects and showed a better organization of TA timing activation in StandTS when compared to SitTS.

Conclusion. Compared to healthy subjects, APAs seem to be altered in both limbs of the post-stroke subjects, with the SOL activation timing being anticipated in both SitTS and StandTS.     

The effect of reinnervation on the distribution of muscle fibre types in the tibialis anterior muscle of the mouse

The distribution of fibre types in the tibialis anterior (TA) muscle of adult mice was examined by means of an immunohistochemical approach, using monoclonal antibodies that recognize different myosin heavy chain isoforms. As has been reported previously, the superficial portion of TA contains almost exclusively type IIB fibres and is almost entirely glycolytic in nature. Following section of the lateral popliteal nerve and rotation of the proximal stump to prevent rematching, it was found that the original pattern was virtually restored within 2 months. One possible explanation for this observation is that the activity pattern of peripheral and deep muscle fibres differs and that this aids in specification of muscle fibre type. Alternatively, the muscle fibres of the superficial portion of TA may be inherently resistant to an alteration of their phenotype with regard to expression of myosin heavy chain.     

Characterization of myosin isoforms in satellite cell cultures from adult rat diaphragm, soleus and tibialis anterior muscles

Satellite cells were isolated by enzymatic dissociation and Percoll gradient centrifugation from adult rat diaphragm, soleus, and tibialis anterior muscles with fairly reproducible yields. Diaphragm and soleus muscle yielded approximately five times more satellite cells than tibialis anterior muscle. According to light microscopic criteria, no morphological differences existed between the satellite cell cultures of different origin. Contrary to the donor muscles, myotubes from the 10-day-cultured satellite cells contained a uniform myosin heavy chain (MHC) pattern with predominance of an immunochemically identified embryonic heavy chain. The three types of cultures displayed a typical embryonic light chain (LC) pattern with LC1emb, LC1f, LC2f, and traces of LC3f. The isomyosin pattern was characterized by four embryonic isomyosins, eM1-eM4, with similar distributions in the three cultures. In summary, these myosin analyses provide no evidence for the existence of satellite cell diversity among three rat muscles of different fiber-type composition, at least not under the applied in vitro conditions.     

Differential expression of two MyoD genes in fast and slow muscles of gilthead seabream ( Sparus aurata)

Members of the myogenic regulatory gene family, including MyoD, Myf5, Myogenin and MRF4, are specifically expressed in myoblast and skeletal muscle cells and play important roles in regulating skeletal muscle development and growth. They are capable of converting a variety of non-muscle cells into myoblasts and myotubes. To better understand their roles in the development of fish muscles, we have isolated the MyoD genomic genes from gilthead seabream (Sparus aurata), analyzed the genomic structures, patterns of expression and the regulation of muscle-specific expression. We have demonstrated that seabream contain two distinct non-allelic MyoDgenes, MyoD1 and MyoD2. Sequence analysis revealed that these two MyoD genes shared a similar gene structure. Expression studies demonstrated that they exhibited overlapping but distinct patterns of expression in seabream embryos and adult slow and fast muscles. MyoD1 was expressed in adaxial cells that give rise to slow muscles, and lateral somitic cells that give rise to fast muscles. Similarly, MyoD2 was initially expressed in both slow and fast muscle precursors. However, MyoD2 expression gradually disappeared in the adaxial cells of 10- to 15-somite-stage embryos, whereas its expression in fast muscle precursor cells was maintained. In adult skeletal muscles, MyoD1 was expressed in both slow and fast muscles, whereas MyoD2 was specifically expressed in fast muscles. Treating seabream embryos with forskolin, a protein kinase A activator, inhibited MyoD1 expression in adaxial cells, while expression in fast muscle precursors was not affected. Promoter analysis demonstrated that both MyoD1 and MyoD2 promoters could drive green fluorescence protein expression in muscle cells of zebrafish embryos. Together, these data suggest that the two non-allelic MyoD genes are functional in seabream and their expression is regulated differently in fast and slow muscles. Hedgehog signaling is required for induction of MyoDexpression in adaxial cells.     

Differential effects of neuropeptides on circular and longitudinal muscles of the crayfish hindgut

Proctolin (Arg-Tyr-Leu-Pro-Thr-OH) and crayfish peptide "DF(2)" (Asp-Arg-Asn-Phe-Leu-Arg-Phe-NH(2)) enhance spontaneous contractions of isolated crayfish hindguts. Both peptides increase the frequency and amplitude of spontaneous, rapid contractions. Proctolin induces a slow contraction, which gives the appearance of an increase in overall tonus. DF(2) has no such effect. To determine whether the peptides affect both longitudinal and circular muscles, hindguts were cut into longitudinal strips and into rings, and contractions were recorded from each. The longitudinal strips generated only rapid contractions, and both peptides increased the frequency and amplitude of such contractions without significantly altering tonus. Rapid contractions were observed in only 1 of 14 preparations of rings. Proctolin induced slow contractions in the rings, and DF(2) had no such effect. The results indicate that neuropeptides have different effects on circular and longitudinal muscles of hindgut.