Comparative risk of common peroneal nerve injury in far anteromedial portal drilling and transtibial drilling in anatomical double-bundle ACL reconstruction.

PURPOSE: The purpose of this study was to investigate the risk of common peroneal nerve injury in FM drilling as compared to transtibial drilling in anatomical double-bundle ACL reconstruction. METHODS: Ten cadaveric knees without ligament injury or significant arthritis were used for this study. Knees were secured at 90° and 120° of flexion. In transtibial drilling groups, a guide pin was drilled through either the anteromedial bundle (AMB) or posterolateral bundle (PLB) tibial insertion site to either the AMB or PLB femoral insertion site (tibial insertion site-femoral insertion site: AM-AM, PL-PL, PL-AM and AM-PL). In FM drilling groups (FM-AM and FM-PL),the pin was drilled at the AMB or PLB femoral insertion site through the FM. We measured the shortest distance between the point at which the pin ran through the lateral cortex of the femur and the ipsilateral common peroneal nerve at a knee flexion of 90° and 120°. RESULTS: At a knee flexion of 90°, the shortest mean distance to the common peroneal nerve was 15.3 mm in the FM-PL group, 13.4 mm in the FM-AM group, 27.9 mm in the PL-PL group, 30.8 mm in the AM-AM group, 37.8 mm in the PL-AM group and 29.5 mm in the AM-PL group. At a knee of flexion 120°, the mean distance was 17.3 mm in the FM-PL group, 18.1 mm in the FM-AM group, 32.2 mm in the PL-PL group, 36.6 mm in the AM-AM group, 38.0 mm in the PL-AM group and 35.2 mm in the AM-PL group. Significant differences were observed between 90° and 120° of knee flexion in the FM-AM, PL-PL, AM-AM and AM-PL groups (P < 0.05). Significant differences were observed at flex 90° between the FM-AM group and AM-AM group, and between the FM-AM group and PL-AM group. Significant differences were observed at flex 120° between the FM-AM group and AM-AM group, between the FM-AM group and PL-AM group and between the FM-PL group and AM-PL group. CONCLUSION: The distance to the peroneal nerve in FM drilling was significantly longer at 120° than at 90° of knee flexion. Therefore, the risk of peroneal injury using FM drilling should decrease at a higher angle of knee flexion.

Temperature-dependent transitions of the myosin-product intermediate at 10 degrees C in the Mn(II)-ATP hydrolysis.

1. While below 10 degrees C, the initial burst of Pi liberation in the hydrolysis of Mn(II)-ATP by heavy meromyosin or myosin subfragment 1 was inhibited by the pre-addition of ADP without any change in the steady-state activity, it was not inhibited above 10 degrees C. The burst size was about one mole per two moles of myosin active sites. 2. Above 10 degrees C, the ultraviolet absorption spectrum of heavy meromyosin induced by ATP in MnCl2 was similar to that induced in MgCl2 and the spectral decay to the ADP-induced level occurred only after all the ATP in the solution was depleted. In contrast, below 10 degrees C the spectrum induced by ATP in MnCl2 decayed to the ADP-induced level within a few seconds after the addition of ATP, although ATP was present in the solution. 3. These two results indicate that in Mn-ATP above 10 degrees C at the burst site there is a myosin*-ADP-Pi complex generated by ATP hydrolysis while below 10 degrees C there is a myosin-product complex identical with the one generated by adding ADP (and Pi) to myosin. 4. At tempertures both above and below 10 degrees C, the Mn-ATP hydrolysis of heavy meromyosin was activated by actin and superprecipitation of actomyosin occurred. Characteristics of these phenomena showed a transition at around 10 degrees C.

Molecular motors: thermodynamics and the random walk.

The biochemical cycle of a molecular motor provides the essential link between its thermodynamics and kinetics. The thermodynamics of the cycle determine the motor's ability to perform mechanical work, whilst the kinetics of the cycle govern its stochastic behaviour. We concentrate here on tightly coupled, processive molecular motors, such as kinesin and myosin V, which hydrolyse one molecule of ATP per forward step. Thermodynamics require that, when such a motor pulls against a constant load f, the ratio of the forward and backward products of the rate constants for its cycle is exp [-(DeltaG + u(0)f)/kT], where -DeltaG is the free energy available from ATP hydrolysis and u(0) is the motor's step size. A hypothetical one-state motor can therefore act as a chemically driven ratchet executing a biased random walk. Treating this random walk as a diffusion problem, we calculate the forward velocity v and the diffusion coefficient D and we find that its randomness parameter r is determined solely by thermodynamics. However, real molecular motors pass through several states at each attachment site. They satisfy a modified diffusion equation that follows directly from the rate equations for the biochemical cycle and their effective diffusion coefficient is reduced to D-v(2)tau, where tau is the time-constant for the motor to reach the steady state. Hence, the randomness of multistate motors is reduced compared with the one-state case and can be used for determining tau. Our analysis therefore demonstrates the intimate relationship between the biochemical cycle, the force-velocity relation and the random motion of molecular motors.

Dissociation of actomyosin by vanadate plus ADP, and decomposition of the myosin-ADP-vanadate complex by actin.

In the presence of vanadate (Vi) and ADP, myosin ATPase forms a stable inactive complex (myosin.ADP.Vi) at the active site. To elucidate the nature of the inactive complex, we studied the effect of Vi plus ADP on the interaction of heavy meromyosin (HMM) with F-actin. 1) Viscosity measurements showed that the actin-HMM rigor complex was dissociated into actin and HMM by Vi and ADP (both 10(-3) M range). 2) When the HMM.ADP.Vi complex isolated by gel filtration was mixed with actin in the absence of free Vi, about 60% of the added HMM formed a complex with actin, and more than 70% of the HMM bound to actin released Vi and ADP. 3) When a mixture of the isolated HMM.ADP.Vi complex with actin was dialyzed against a buffer without free Vi and free ADP, only less than 10% of Vi and ADP, which were originally bound to the HMM, were retained in the dialysis tube after 4 days. In contrast, if actin was omitted, about 80% of Vi and ADP were retained. 4) These results indicate that the HMM.ADP-Vi complex is dissociated from actin, and that Vi and ADP originally trapped at the HMM active site can be almost completely released from the active site by actin if free (released) Vi and ADP are concomitantly removed.

Temperature-dependent transitions of the myosin-product intermediate at 10 degrees during Mn(II)-ATP hydrolysis by myosin from rabbit psoas muscle.

The initial burst of Pi liberation during the hydrolysis of Mn(II)-ATP by heavy meromyosin from rabbit psoas muscle was investigated. Below 10 degrees, the initial burst of Pi liberation was inhibited by the pre-addition of ADP without any change in the steady-state activity, but it was not inhibited above 10 degrees. The burst size was about one mole per mole of heavy meromyosin. The initial burst of Pi liberation in Mg-ATP hydrolysis at 8 degrees, however, was not inhibited by the pre-addition of ADP. These results, obtained with psoas muscle heavy meromyosin, were almost the same as those obtained with heavy meromyosin from rabbit leg and back muscles (Hozumi and Tawada (1975) Biochim. Biophys. Acta 376, 1-12) and, therefore, indicate that in Mn-ATP above 10 degrees there is at the burst site a predominant myosin -product complex generated by ATP hydrolysis. Similarly, below 10 degrees there is a myosin-product complex identical with the one generated by adding ADP (and Pi) to myosin.

Separation of myosin subfragment 1 into two fractions, one having the burst site and the other having the non-burst site.

During Mn(II)-ATP hydrolysis by myosin, the predominant intermediate formed at the burst site of the enzyme below 10 degrees is the myosin-ADP complex formed by adding ADP to myosin, while above 10 degrees it is the myosin -ADP-P1 complex generated by ATP hydroolysis (Yazawa, Morita, & Yagi (1973) J. Biochem. 74, 1107; Hozumi & Tawada (1975) Biochim. Biophys. Acta 376, 1; Tawada & Yoshida (1975) J. Biochem. 78, 293). It is suggested that the second (non-burst) site of myosin predominantly forms the myosin-ATP complex (Hozumi & Tawada, ibid.). From these findings, it is expected that (i) myosin subfragment 1 (S1) having the burst site is bound to actin in Mn(II)-ATP solution containing ADP below 10 degrees, because it forms the S1-ADP complex even in the presence of ATP; (ii) the other S1, i.e., that having the non-burst site, is dissociated from actin, because it forms the S1-ATP complex. These two expectations were confirmed by viscosity measurements of acto-S1 solutions, giving a basis for the separation of S1 into two fractions: one having the burst site and the other having the non-burst site. S1 having the non-burst site could be extracted from partially papain [EC 3.4.22.2]-digested myofibrils of rabbit skeletal muscle with a solution containing MnCl2, ATP, and ADP at 0 degrees. S1 having the burst site was extracted from myofibrils already used for the extraction of S1 having the non-burst site, with a solution containing MgCl2 and ATP at 20 degrees. The former S1 fraction had Mg-ATPase [EC 3.6.1.3] activity, but scarcely showed any initial burst of Pi liberation. The latter S1 showed a Pi burst of more than 0.5 (M/M). The steady state ATPase activity of the former S1 was slightly higher than that of the latter. The burst size of normal S1, i.e., that extracted from papain-digested myofibrils with Mg-PPi or Mg-ATP, was 0.5 (M/M). The ultraviolet absorption spectrum of the non-burst type S1 was not changed by ADP but was changed by ATP, though the difference spectrum was distinct from that of normal S1 and the difference molar extinction coefficient at 289 nm was only 20% of that of normal S1. No significant difference was seen in the compositions of these two S1's and normal S1, as determined by SDS gel electrophoresis.

Trinitrophenylation of the reactive lysine residue in double-headed myosin in the presence of PP.

Lys-83 in the heavy chain of rabbit skeletal muscle myosin is rapidly and stoichiometrically modified by trinitrobenzene sulfonate. Other authors claimed that the half-stoichiometric trinitrophenylation of Lys-83 in myosin in the presence of PPi was correlated to a Pro/Ser microheterogeneity at the 78th residue position in the heavy chain [Miyanishi, T., Maita, T., Matsuda, G., & Tonomura, Y. (1982) J. Biochem. 91, 1845-1853]. However, our recent studies with chymotryptic subfragment 1 (S1) instead of myosin showed no such correlation between the half-stoichiometric trinitrophenylation and the Pro/Ser microheterogeneity [Komatsu, H. & Tawada, K. (1993) J. Biol. Chem. 268, 16974-16978]. Since the global structure of the head portion of myosin is different from that of chymotryptic S1 that lacks DTNB light chain, it could be argued that the difference is due to the structural difference between chymotryptic S1 and myosin. We hence reexamined the situation with myosin, and obtained the same results as found with S1: (i) Lys-83 in myosin was half-stoichiometrically trinitrophenylated in the presence of PPi, although it was stoichiometrically modified in the absence of PPi; (ii) there was a Pro/Ser microheterogeneity at the 78th position in the myosin heavy chain, which was not correlated to the half-stoichiometric trinitrophenylation of Lys-83 in the presence of PPi.

Temperature-dependence of tension development by glycerinated muscle fibers of rabbit psoas in Mn (II)-ATP and Mg-ATP solutions.

The tension of single fibers isolated from glycerinated rabbit psoas muscle was measured at various temperatures using Mg-ATP or Mn-ATP as a substrate. The tension developed in Mn-ATP was 80-89% of that in Mg-ATP at 4 degrees-16 degrees, and both tensions decreased as the temperature was reduced. Myosin forms the myosin-product complex predominantly generated on admixture with ADP (and Pi) at the burst site during Mn(II)-ATP hydrolysis below 10 degrees, while it forms the myosin-product complex predominantly formed via ATP hydrolysis upon hydrolysis above 10 degrees, as it does during Mg-ATP hydrolysis (Hozumi & Tawada (1975) Biochim. Biophys. Acta 376, 1; Tawada & Yoshida (1975) J. Biochem. 78, 293; Yazawa & Morita (1973) J. Biochem. 74, 1107). Since the cycle time of cross-bridge attachment to and detachment from actin in muscle is about 1-10 sec and because the spontaneous decay time of the myosin-product complex into the myosin-product complex in the absence of actin is less than 1 sec, then if most of the cross-bridges are detached from actin as suggested by X-ray data, it can be inferred that most of the cross-bridges detached from actin may form the predominant myosin-product complex in Mn-ATP below 10 degrees. If this is so, the tension development in Mn-ATP below 10 degrees cannot be compatible with some muscle models which assume the formation of the myosin-product complex by the cross-bridges prior to combination with actin during contraction.

Characterization of the ATPase active site in myosin subfragment-1 with the use of vanadate plus ADP as a reversible "affinity-labeling" reagent: evidence for heterogeneity in the active sites.

Our previous work showed that the active site heterogeneity in heavy meromyosin (HMM) becomes evident when highly reactive SH-groups in HMM are modified by thimerosal (Kawamura, Higuchi, Emoto, & Tawada (1985) J. Biochem. 97, 1583-1593). The heterogeneity was revealed by "affinity-labeling" analysis with vanadate plus ADP, which was developed in the previous paper. To see whether this heterogeneity is due to the head-head interaction or two different alkali light chains present in HMM, we carried out similar studies with myosin subfragment-1 (S1) and one of the isozymes, S1(A1), which contains only the alkali light chain 1, and obtained essentially the same results as those previously obtained with HMM. The S1 results are easily explained by the same hypothesis previously used for explaining the HMM results: SH-modified S1 or S1(A1) contains two kinds of active site in a 1:1 ratio with almost the same ATPase activity: one hydrolyzes ATP by a mechanism giving a protein Trp fluorescence enhancement, whereas the other hydrolyzes ATP by another mechanism giving no fluorescence enhancement.

Separation of SH-modified myosin subfragment-1 (A1) isozyme into two distinct equimolar fractions by an affinity chromatography.

Our previous kinetic studies indicated that SH-modified myosin subfragment-1 A1 isozyme (S1(A1] contains at least two different types of active sites (Emoto, Y., Kawamura, T., & Tawada, K. (1985) J. Biochem. 98, 735-745). In those studies we have modified highly reactive SH-groups in S1(A1) with thimerosal. In this work, we separated the modified S1(A1) into two equimolar fractions by affinity chromatography with agarose-ADP. For the separation, Mg2+ in the elution buffer was indispensable. Although the two fractions appeared to have the same number of modified SH-groups per mol of S1, they had different enzymic and fluorescent properties. SH-modification with an excess of thimerosal for a much longer duration did not change any of the results: not the chromatographic profile, the properties of the two fractions, nor the number of modified SH-groups. Hence the two different populations were not generated by incomplete modification. After reduction with dithiothreitol, however, the differences between the two fractions disappeared. When we separately re-modified the reduced fractions and re-chromatographed them, in each case we again obtained two fractions, which had the same properties as the two fractions obtained from the original modification with thimerosal. These results demonstrate that the active site heterogeneity in SH-modified S1(A1) had no intrinsic origin in the unmodified S1: it was introduced by the SH-modification, but by an unknown mechanism(s) other than incomplete modification.

Temperature-dependence of tension development by glycerinated muscle fibers of rabbit psoas in Mg-ITP solution.

The isometric tension of single fibers isolated from glycerinated rabbit psoas muscle was measured at various temperatures using Mg-ITP as a substrate. The tension developed in Mg-ITP decreased linearly as the temperature was reduced from 24 degrees C to 4 degrees C. Myosin formed the myosin--product complex predominantly via ATP hydrolysis at the burst site during Mg-ATP hydrolysis, irrespective of temperature, and the tension developed in Mg-ATP decreased linearly as the temperature decreased (Yoshida and Tawada (1976) J. Biochem. 80, 861). During Mg-ITP hydrolysis, myosin forms the myosin*-product complex predominantly at the burst site above 20 degrees C, while myosin forms the myosin*-substrate complex below 8 degrees C (Hozumi (1976) Eur. J. Biochem. 63, 241). However, the temperature dependence of tension development in Mg-ITP is linear, as with Mg-ATP, as mentioned above. This temperature dependence is not compatible with some muscle models which assume the formation of the myosin*-product complex by cross-bridges prior to combination with actin during contraction.

Myosin-free ghosts of single fibers and an attempt to re-form myosin filaments in the ghost fibers.

With the final aim of replacing myosin in a single muscle fiber, a technique for removing myosin almost completely from single fibers was developed and an attempt to "re-form" thick filaments in the myosin-free ghosts of single fibers was made. Complete removal of myosin from single glycerol-treated rabbit psoas fibers with Hasselbach-Schneider solution was difficult. However, when skinned glycerol-treated fibers were used and 1% (v/v) Triton X-100 was added to the Hasselbach-Schneider solution, almost complete removal of myosin was possible. The myosin-free ghosts of skinned single fibers were very fragile but retained the overall structure. In the ghost fibers, Z-membranes and thin filaments remained. The ghost fibers, after irrigation with myosin, underwent contraction upon addition of Mg-ATP. In the myosin-irrigated fibers, thick filaments were re-formed in lengths from one Z-membrane to the other Z-membrane of a sarcomere, running parallel to the thin filaments. The packing of these two filaments was not good. The isometric tension developed by the irrigated fibers upon addition of mg-ATP was about 10% of the tension developed by untreated fibers. The weak tension developed by irrigated fibers is probably due to the irregular packing of the thick and thin filaments in the fibers. The ghost fibers also contracted, though only slightly, upon addition of Mg-ATP after irrigation with heavy meromyosin.

An ESR study of the Mn(II)-heavy meromyosin system.

The Mn(II)-heavy meromyosin system was studied by measuring the ESR spectrum of Mn(II). The temperature dependence of the line width parameter W(1, t) of a freshly prepared sample changes at around 7-10 degrees C, where W(1, t) is the reciprocal of the peak-to-peak height of the lowest magnetic field component of the hyperfine structure. It is shown that the change in the slope of W(1, t) at 7-10 degrees C is due to a change in the structure of Mn(II)-heavy meromyosin or a change in the interaction between Mn(II) and heavy meromyosin without ATP. This result is in accord with the recently reported observations that heavy meromysin ATPase activity showed different temperature dependence above and below 10 degrees C in the presence of Mn(II). The characteristics of the spectrum of the Mn(II)-heavy meromyosin system in the liquid state between 2 degrees C and 20 degrees C are compared with those of a frozen sample of Mn(II)-heavy meromyosin in a low temperature region (-50-0 degrees C) and with those of the lyophilized material. The forbidden transitions are observed, and hence the zero field splitting parameter can be obtained. It is 115 +/- 15 gauss at -50 degrees C, and decreases with increase of the temperature to 70 +/- 15 gauss at 20 degrees C.

Relationship between the ATPase activity and the ATP-induced fluorescence enhancement of SH-modified heavy meromyosin during its fractional inactivation by vanadate plus ADP: evidence for heterogeneity in the active sites.

We have examined whether heavy meromyosin (HMM) consists of a single kind of active site by analyzing the changes in the relative MgATPase activity and the relative amplitude of the ATP-induced fluorescence enhancement of the protein when the fraction of HMM "affinity"-labeled by vanadate plus ADP was varied. The analysis is based on a prediction that these two changes should be proportional to each other if myosin consists of a single kind of active site and generates the rate-limiting myosin**product complex emitting enhanced fluorescence. Although the difference between these two changes was very small with native HMM, it was large with HMM in which 5 fast-reactive sulfhydryl-groups per head were pre-modified with thimerosal. The difference indicated the existence of heterogeneous active sites in the SH-modified HMM. The results were best explained in terms of the hypothesis that fifty percent of the active site splits MgATP by a mechanism giving a fluorescence enhancement whereas the other fifty percent splits MgATP by another mechanism giving no fluorescence enhancement. Two possible explanations for the existence of heterogeneous active sites in the SH-modified HMM are discussed. One assumes the pre-existence of some sort of 1:1 heterogeneity in the micro-environment of the active sites and the other, which is considered less likely, assumes the introduction of the heterogeneity as a result of the SH-modification.

Non-polymerizable tropomyosin and control of the superprecipitation of actomyosin.

Non-polymerizable tropomyosin was prepared by the digestion of several C-terminal residues of tropomyosin with carboxypeptidase A [EC 3.4.12.2]. The intrinsic viscosity and molecular weight of the non-polymerizable tropomyosin were almost the same as those of untreated tropomyosin. Like untreated tropomyosin, the non-polymerizable tropomyosin in combination with troponin repressed the superprecipitation of actomyosin in the absence of calcium, while this repression was released by addition of calcium. However, the curve representing the superprecipitation rate as a function of pCa was less steep than that found with actomyosin containing untreated tropomyosin: in the former case, the rate increased to a plateau over about 2 pCa units, while in the latter case, it did so over about 1 pCa unit. These experimental results provide evidence that the "co-operation" in the regulation mechanism of skeletal muscle contraction, which is indicated by the steep curve of the contraction versus pCa relation, is mediated by tropomyosin-tropomyosin interaction along the thin filament.

Cross-linking of contractile proteins from skeletal muscle by treatment with microbial transglutaminase.

The action on muscle proteins of microbial transglutaminase (MTGase), which catalyzes the formation of a "zero-length" covalent cross-link between glutamine and lysine residues in peptides, was studied in order to define a basis for future application of MTGase cross-linking to the study of muscle protein interaction. We examined the cross-linking of skeletal muscle myosin, myosin subfragments, actin, and myofibrils by treatment with MTGase and the possible side-effects of the cross-linking on the enzymic activity of myosin, and found that the rod portions of myosin in myosin filaments were quickly cross-linked to each other by the action of MTGase, but myosin subfragment 1 was not cross-linked to actin. The MgATPase activities at 0.5 M KCl of myosin, heavy meromyosin, subfragment 1, and subfragment 1-actin were not significantly affected by the MTGase reaction. A very small fraction of the head portion of heavy meromyosin was cross-linked to actin in their rigor complexes by MTGase, and the ATPase activity at 0.5 M KCl of the cross-linked heavy meromyosin-actin complexes was slightly enhanced.

Synchronous firing patterns of a set of insect neurosecretory cells.

The number of active cells in each synchronous firing event in a set of 10 neurosecretory cells in the silkmoth Bombyx mori was estimated from the amplitude and waveform of compound action potentials. One to 10 cells discharged an action potential within a period of 30 ms and one to two or nine to 10 units became active more frequently in a synchronous firing event. Numbers of active cells fluctuated like a sequence of pseudo random numbers, though the same number of cells tended to fire in two successive firing events of a short interval. These patterns suggest that electrical coupling may mediate synchronous firings in the insect neurosecretory cell system.

Fluctuations in sliding motion generated by independent and random actions of protein motors.

We consider theoretical fluctuations in the in vitro sliding movement of individual cytoskeletal filaments generated by an ensemble of protein motors whose actions are assumed to be statistically independent and random. We show that the mean square deviation of the sliding distances of a filament for a given period of time around their average is proportional to the inverse of the filament length. This result provides a basis for an experimental test of the general assumption on the independent and random actions of protein motors.

Force production by chemically crosslinked myosin-actin crossbridges in rabbit skinned fibers in response to MgATP depletion.

In order to study the contractile property of myosin crossbridges attached to thin filaments, myosin heads were crosslinked to the filaments at their interface in single skinned rabbit psoas fibers with a zero-length chemical crosslinker, 1-(3-dimethylamino-propyl)-3-ethylcarbodiimide (EDC). The results obtained show that a partially crosslinked single fiber produces a large rigor-like force when MgATP is depleted from the myofibrillar space. Such crosslinked fibers contain two types of crosslinked myosin heads: one with one of the two heads of the myosin molecule crosslinked to actin with the other head uncrosslinked; the other has both heads crosslinked to actin. The results of this work suggest that a crosslinked myosin head of the former type produces a much larger force than the latter type.

Length dependence of displacement fluctuations and velocity in microtubule sliding movement driven by sea urchin sperm outer arm beta dynein in vitro.

We have studied the dependence on microtubule length of sliding velocity and positional fluctuation from recorded trajectories of microtubules sliding over sea urchin sperm outer arm beta dynein in a motility assay in vitro. The positional fluctuation was quantified by calculating the mean-square displacement deviation from the average, the calculation of which yields an effective diffusion coefficient. We have found that (1) the sliding velocity depends hyperbolically on the microtubule length, and (2) the effective diffusion coefficients do not depend on the length for sufficiently long microtubules. The length dependence of the sliding velocity indicates that the duty ratio, defined as the force producing period over the total cycle time of beta dynein interaction with microtubule, is very small. The length independence of the effective diffusion coefficient indicates that there is a correlation in the sliding movement fluctuation of microtubules.