Orthostasis fails to produce active limb venoconstriction in adolescents.

Orthostasis is characterized by translocation of blood from the upper body and thorax into dependent venous structures. Although active splanchnic venoconstriction is known to occur, active limb venoconstriction remains controversial. Based on prior work, we initially hypothesized that active venoconstriction does occur in the extremities during orthostasis in response to baroreflex activation. We investigated this hypothesis in the arms and legs of 11 healthy volunteers, aged 13-19 yr, using venous occlusion strain gauge plethysmography to obtain the forearm and calf blood flows and to compute the capacitance vessel volume-pressure compliance relation. Subjects were studied supine and at -10, +20, and +35 degrees to load the baroreflexes. With +20 degrees of tilt, blood flow decreased and limb arterial resistance increased significantly (P < 0.05) compared with supine. With +35 degrees of tilt, blood flow decreased, limb arterial resistance increased, and heart rate increased, indicating parasympathetic withdrawal and sympathetic activation with arterial vasoconstriction. The volume-pressure relation was unchanged by orthostatic maneuvers. The results suggest that active venoconstriction in the limbs is not important to mild orthostatic response.     

Isoproterenol fails to produce myocardial necrosis in streptozotocin-induced diabetic rats.

Biochemical alterations in the hearts of non-diabetic and 5 weeks of streptozotocin-induced diabetic rats following isoproterenol (ISO) administration were compared. Serum lactate dehydrogenase (LDH) and myocardial adenosine triphosphate (ATP), creatine phosphate (CP), lactate and glycogen were used as indices of myocardial injury. Hearts from diabetic rats (blood glucose greater than 350 mg/dl), before ISO administration, had normal lactate levels but significantly low high-energy phosphate (HEP) levels and high glycogen levels in comparison to non-diabetic rats. No difference was observed in serum LDH levels between these two groups. ISO administration to non-diabetic rats caused myocardial necrosis as evidenced by a significant depletion of myocardial glycogen and HEPs along with significant myocardial lactate accumulation and an increase in serum LDH. However, the hearts from diabetic rats failed to show any significant HEP depletion, accumulation of lactate and leakage of LDH into serum following ISO-administration, though myocardial glycogen level was significantly lowered. These observations, in conjunction with earlier reports, point to the hypothesis that, in diabetes, there are certain alterations in the sarcolemma which hamper the process by which ISO causes myocardial necrosis.     

Larval apical sensory organ in a neritimorph gastropod,an ancient gastropod lineage with feeding larvae

The Neritimorpha is an ancient clade of gastropods that may have acquired larval planktotrophy independently of the evolution of this developmental mode in other gastropods (caenogastropods and heterobranchs). Neritimorphs are therefore centrally important to questions about larval evolution within the Gastropoda, but there is very little information about developmental morphology through metamorphosis for this group. We used immunolabeling (antibodies binding to acetylated α-tubulin and serotonin) and serial ultrathin sections for transmission electron microscopy to characterize the apical sensory organ in planktotrophic larvae of a marine neritimorph. The apical sensory organ of gastropod larvae is a highly conserved multicellular sensory structure that includes an apical ganglion and often an associated ciliary structure. Surprisingly, the apical ganglion of Nerita melanotragus (Smith, 1884) does not have typical ampullary neurons, a type of sensory neuron consisting of a cilia filled inpocketing that has been described in all other major gastropod groups. N. melanotragus has cilia-filled pockets embedded within the apical ganglion, but these so-called “sensory cups” are cassettes of multiple cells: one supporting cell and up to three multiciliated sensory cells. We suggest that an internalized pocket that is filled with cilia and open to the exterior via a narrow pore may be essential architectural features for whatever sensory cues are detected by ampullary neurons and sensory cups; however, morphogenesis of these features at the cellular level has undergone evolutionary change. We also note a correlation between the number of sensory elements consisting of cilia-filled pockets within the larval apical sensory organ of gastropods and morphological complexity of the velum or length of the trochal ciliary bands.     

Rapid vasodilation in response to a brief tetanic muscle contraction.

To test the hypothesis that vasodilation occurs because of the release of a vasoactive substance after a brief muscle contraction and to determine whether acetylcholine spillover from the motor nerve is involved in contraction-induced hyperemia, tetanic muscle contractions were produced by sciatic nerve stimulation in anesthetized dogs (n = 16), instrumented with flow probes on both external iliac arteries. A 1-s stimulation of the sciatic nerve at 1. 5, 3, and 10 times motor threshold increased blood flow above baseline (P < 0.01) for 20, 25, and 30 s, respectively. Blood flow was significantly greater 1 s after the contraction ended for 3 and 10 x motor threshold (P < 0.01) and did not peak until 6-7 s after the contraction. The elevations in blood flow to a 1-s stimulation of the sciatic nerve and a 30-s train of stimulations were abolished by neuromuscular blockade (vecuronium). The delayed peak blood flow response and the prolonged hyperemia suggest that a vasoactive substance is rapidly released from the contracting skeletal muscle and can affect blood flow with removal of the mechanical constraint imposed by the contraction. In addition, acetylcholine spillover from the motor nerve is not responsible for the increase in blood flow in response to muscle contraction.     

离体心肌“生理性”收缩的计算机伺服系统

扩充了A/D接口的Z-80微机和编制的软件,与肌力计和力位移双态换能器组成伺服系统,可以自动控制换能器金属杆的工作状态和“后负荷”水平,使离体心肌产生时相顺序类同于射血心室的四个时相“生理性”收缩,从而获得心肌的张力长度关系、作功量等心肌力学信息,并可同步观察收缩末期张力长度关系和张力速度关系。     

Theory of muscle contraction II. Isotonic contraction

The theory of muscle contraction developed in Part I is extended to non-isometric cases. The basic feature of the approach is the strong viscous coupling of the movement of the counterionic (K⁺) layer with the movement of I-filaments. The surface conductance of the K⁺ layer governs the flux of H⁺ along the I-filaments which in turns regulates the rate of ATP hydrolysis. The energy output of the muscle becomes the function of its mechanical activity. By assuming linear dependence of the K⁺ layer's surface conductance on the velocity of shortening Hill's equation has been derived. With a set of reasonably chosen values of the basic parameters of the theory the values of Hill's constants have been computed. The theory has been also shown to provide the observed dependence of the isometric tension on the degree of the myofilamental overlap.     

Theory of muscle contraction: I. Isometric contraction

For each molecule of ATP hydrolyzed by the ATPase at the subfragment 1 of the heavy meromyosin, one H⁺ is produced and remains associated with the myosin heads until a contact with the G-actins of the I-filaments is established. This contact is brought about by the calcium ions released in the sarcomeres by the sarcoplasmic reticulum at the arrival of nerve impulses. A rapid flux of protons along the I-filaments towards the Z-membrane down the concentration gradient leads to the buildup of a diffusion potential which in turn causes a charge-compensating movement of the diffused cationic layer around the I-filaments in the opposite direction. The latter movement exerts a viscous drag on the actins and tends to move the I-filaments deeper into the inter-A-filament spaces towards the M-line. A consistent and straightforward theory of muscular contraction is developed on these lines. The value of the isometric tension in striated muscle fiber of frog at slack length calculated on the basis of this theory agrees well with the measured value.     

Ethanol administration fails to produce hypoglycemia in fasted chickens (Gallus domesticus)

Chickens weighing approx. 1500 g were fasted 64 hr and then continuously infused with [6-3H]glucose to determine effects of ethanol on plasma glucose concentrations and on rates of glucose turnover. Ethanol infusions (222 or 444 mumol/min X kg-1 body weight) did not cause hypoglycemia although the high dose infusion slightly decreased the rate of glucose turnover. Metabolite ratios measured in livers of chickens infused with the high dose of ethanol indicated that the hepatic cytosolic redox state was relatively unchanged. Chickens have an unusual resistance to ethanol-induced hypoglycemia.     

Calcium regulation of muscle contraction.

Calcium triggers contraction by reaction with regulatory proteins that in the absence of calcium prevent interaction of actin and myosin. Two different regulatory systems are found in different muscles. In actin-linked regulation troponin and tropomyosin regulate actin by blocking sites on actin required for complex formation with myosin; in myosin-linked regulation sites on myosin are blocked in the absence of calcium. The major features of actin control are as follows: there is a requirement for tropomyosin and for a troponin complex having three different subunits with different functions; the actin displays a cooperative behavior; and a movement of tropomyosin occurs controlled by the calcium binding on troponin. Myosin regulation is controlled by a regulatory subunit that can be dissociated in scallop myosin reversibly by removing divalent cations with EDTA. Myosin control can function with pure actin in the absence of tropomyosin. Calcium binding and regulation of molluscan myosins depend on the presence of regulatory light chains. It is proposed that the light chains function by sterically blocking myosin sites in the absence of calcium, and that the "off" state of myosin requires cooperation between the two myosin heads. Both myosin control and actin control are widely distributed in different organisms. Many invertebrates have muscles with both types of regulation. Actin control is absent in the muscles of molluscs and in several minor phyla that lack troponin. Myosin control is not found in striated vertebrate muscles and in the fast muscles of crustacean decapods, although regulatory light chains are present. While in vivo myosin control may not be excluded from vertebrate striated muscles, myosin control may be absent as a result of mutations of the myosin heavy chain.     

The neural control of contraction in a fast insect muscle.

The wing muscles used in singing by the katydid, Neoconocephalus robustus, are extraordinarily fast. At 35 degrees C, the animal's thoracic temperature during singing, an isometric twitch lasts only five to eight msec (onset to 50% relaxation) and the fusion frequency of these muscles is greater than 400 Hz. Stimulating the motornerve to a singing muscle initiates a short (2.5 msec at 35 degrees C), sometimes overshooting depolarization of the muscle fibers. Despite their spike-like appearance, the electrical responses are largely synaptic potentials. The muscle membrane appears to be capable of only weak, electrically-excitable, depolarizing electrogenesis. The short synaptic potentials result in part from rapidly-developing delayed rectification, in part from a low resting membrane resistance (Rm = 162 omega cm2) and a concomitantly short membrane time constant (about 1.5 msec).     

An activating amino acid substitution in the c-abl oncogene protein fails to produce a local conformational change

Thebcr-abl chimeric gene of Philadelphia chromosome positive chronic myelogenous leukemias is only weakly transforming. This transformation activity is greatly enhanced by a Lys-for-Glu substitution at position 832 in the c-abl gene, as occurs in the highly transforming v-abl genes. It has been suggested that this mutation results in a significant structural change in the encoded protein product. Using conformational energy analysis, we have determined the allowed low-energy conformations for residues 828–836 of this protein with Lys and Glu at position 832. In both cases, the overwhelmingly preferred conformation for this region is a bend-helix motif. The helix terminates at residue 836, and there are no discernible differences in conformation between the Lys- and Glu-containing sequences. These results suggest that the activating amino acid substitution at position 832 in the c-abl protein product does not produce its effect via a local conformational change.     

Hsp27 is a mediator of sustained smooth muscle contraction in response to bombesin.

We have identified the low MW 27 kD heat shock protein as a major phosphoprotein constituent of smooth muscle and have investigated its potential role in agonist induced smooth muscle contraction. The neuropeptides bombesin and substance P, which are present in neurons of the anorectal region, induce contraction of isolated smooth muscle cells from this region by activating different intracellular pathways. Substance P-induced contraction is 1,4,5-inositol trisphosphate (IP3)/calmodulin dependent, while contraction induced by bombesin is mediated by a protein kinase C (PKC)-dependent pathway. The sustained contraction induced by bombesin or exogenous PKC was blocked by preincubation of cells with monoclonal antibodies to hsp27, while the transient contraction induced by substance P or IP3 was unaffected by the antibodies. Preincubation with isotype matched control antibodies had no inhibitory effect on contraction induced in response to the agents used. These data support a novel role for hsp27 in the non calmodulin mediated sustained contraction induced by bombesin or PKC.     

A codon change in beta-tubulin which drastically affects microtubule structure in Drosophila melanogaster fails to produce a significant phenotype in Saccharomyces cerevisiae.

The relative uniformity of microtubule ultrastructure in almost all eukaryotic cells is thought to be a consequence of the conserved elements of tubulin sequence. In support of this idea, a mutation in a beta-tubulin gene of Drosophila melanogaster, occurring at a highly conserved position, produces U-shaped microtubules, suggesting a defect in either nucleation or packing during assembly (M. T. Fuller, J. H. Caulton, J. A. Hutchens, T. C. Kaufman, and E. C. Raff, J. Cell Biol. 104:385-394, 1987, and J. E. Rudolph, M. Kimble, H. D. Hoyle, M. A. Subler, and E. C. Raff, Mol. Cell. Biol. 7:2231-2242, 1987). Surprisingly, we find that introducing the same mutation into the sole beta-tubulin gene of Saccharomyces cerevisiae has virtually no consequences for microtubule structure or function in that organism.     

Protons act as a transmitter for muscle contraction in C. elegans

Muscle contraction is normally mediated by the release of neurotransmitters from motor neurons. Here we demonstrate that protons can act as a direct transmitter from intestinal cells to stimulate muscle contraction. During the C. elegans defecation motor program the posterior body muscles contract even in the absence of neuronal inputs or vesicular neurotransmission. In this study, we demonstrate that the space between the intestine and the muscle is acidified just prior to muscle contraction and that the release of caged protons is sufficient to induce muscle contraction. PBO-4 is a putative Na+/H+ ion exchanger expressed on the basolateral membrane of the intestine, juxtaposed to the posterior body muscles. In pbo-4 mutants the extracellular space is not acidified and the muscles fail to contract. The pbo-5 and pbo-6 genes encode subunits of a "cys-loop" proton-gated cation channel required for muscles to respond to acidification. In heterologous expression assays the PBO receptor is half-maximally activated at a pH of 6.8. The identification of the mechanisms for release and reception of proton signals establishes a highly unusual mechanism for intercellular communication.