Direct observation of oriented behavior of actin filaments interacting with desmin intermediate filaments.

BACKGROUND: Associations between actin filaments (AFs) and intermediate filaments (IFs) are frequently observed in living cells. The crosstalk between these cytoskeletal components underpins cellular organization and dynamics; however, the molecular basis of filamentous interactions is not fully understood. Here, we describe the mode of interaction between AFs and desmin IFs (DIFs) in a reconstituted in vitro system. METHODS: AFs (rabbit skeletal muscle) and DIFs (chicken gizzard) were labeled with fluorescent dyes. DIFs were immobilized on a heavy meromyosin (HMM)-coated collodion surface. HMM-driven AFs with ATP hydrolysis was assessed in the presence of DIFs. Images of single filaments were obtained using fluorescence microscopy. Vector changes in the trajectories of single AFs were calculated from microscopy images. RESULTS: AF speed transiently decreased upon contact with DIF. The difference between the incoming and outgoing angles of a moving AF broadened upon contact with a DIF. A smaller incoming angle tended to result in a smaller outgoing angle in a nematic manner. The percentage of moving AFs decreased with an increasing DIF density, but the speed of the moving AFs was similar to that in the no-desmin control. An abundance of DIFs tended to exclude AFs from the HMM-coated surfaces. CONCLUSIONS: DIFs agitate the movement of AFs with the orientation. DIFs can bind to HMMs and weaken actin-myosin interactions. GENERAL SIGNIFICANCE: The study indicates that apart from the binding strength, the accumulation of weak interactions characteristic of filamentous structures may affect the dynamic organization of cell architecture.

Proteolysis and Flavor Characteristics of Serrano Ham Processed under Different Ripening Temperature Conditions.

UNLABELLED: Physicochemical, proteolysis and sensory characteristics of Serrano hams processed under low, medium and high ripening temperature conditions (RTC), with respective average temperatures of 9.3, 14.3, and 19.1 °C, were determined throughout a 15-mo period. In addition, quantitative relationships among variables were calculated. Medium and high RTC hams showed lower moisture contents and lower levels of low- and high-ionic-strength soluble proteins than low RTC hams. At 15 mo, aldolase was the most abundant low-ionic-strength soluble protein and actin the most abundant high-ionic-strength soluble protein in all hams while creatine kinase was no longer detected and H-meromyosin was detected only in low and medium RTC hams. Levels of all the molecular-weight peptide fractions increased during ripening, with higher factors of increase for the fractions of lower molecular weight. Total free amino acids were at significantly higher concentrations in medium and high RTC hams than in low RTC hams from month 7 onwards. The correlations of flavor preference and flavor intensity with ripening time, thermal integral, total free amino acids and most individual free amino acids were highly significant, while raw-meat taste was negatively correlated with all those variables. From month 5 to month 9 of ripening, development of a high quality flavor evolved more rapidly in medium RTC hams, flavor intensity increased at a faster rate in high RTC hams and raw-meat taste declined more rapidly in medium and high RTC hams. Medium and high RTC may be applied to accelerate the ripening process of Serrano ham without impairing flavor preference. PRACTICAL APPLICATION: Medium and high ripening temperature conditions (RTC) may be applied to Serrano ham in order to enhance the phenomena associated with ripening, without loss of product quality. Moisture loss, degradation of proteins and formation of free amino acids were accelerated in medium and high RTC hams. From month 5 to month 9 of ripening, development of a high quality flavor evolved more rapidly in medium RTC hams, flavor intensity increased at a faster rate in high RTC hams, and raw-meat taste declined more rapidly in medium and high RTC hams.

Curtailing Oxidation-Induced Loss of Myosin Gelling Potential by Pyrophosphate Through Shielding the S1 Subfragment.

UNLABELLED: In muscle food processing, where oxidation is inevitable, phosphates are usually added to improve water binding. This present study attempted to investigate the interactive roles of protein oxidation and pyrophosphate (PP) during thermal gelation of myosin. Myosin isolated from pork muscle was solubilized in 0.5 M NaCl at pH 6.2 then oxidatively stressed with an iron-redox cycling system that produces hydroxyl radicals with or without 1 mM PP and 2 mM MgCl2 at 4 °C for 12 or 24 h then heated to 50 °C at 1.3 °C/min. Protein conformational stability was measured by differential scanning calorimetry, and covalent cross-linking was examined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis following chymotrypsin digestion. The binding of PP to myosin suppressed disulfide bond formation in myosin subfragments 1 and 2 and partially inhibited oxidation-initiated cross-linking of heavy meromyosin during myosin gelation with a lesser effect on light meromyosin. In the presence of PP, myosin exhibited less loss of conformational integrity upon oxidation than myosin without PP. Rheological analysis from 20 to 75 °C indicated up to 32% decreases (P < 0.05) in elastic modulus (G') of myosin gels due to oxidation. However, the presence of 1 mM PP, which also lowered the gelling capacity of myosin, inhibited the oxidation-induced G' by nearly half (P < 0.05). These results suggest that the protection of myosin head from oxidative modification by PP can be a significant factor for the minimization of gelling property losses during cooking of comminuted meats. PRACTICAL APPLICATION: The association of myosin S1 subfragment possibly S2 as well with pyrophosphate prevents extensive myosin head­head cross-linking. This alleviates the negative impact of oxidation on the gel formation of myosin, an expected main form of myofibrillar protein due to pyrophosphate-induced actomyosin dissociation. Likewise, oxidative S1­S1 association inhibits the binding of pyrophosphate thereby reducing its gel-weakening effect. The mutual constraining roles of oxidation and pyrophosphate can be a significant factor for the minimization of gelling property losses during the manufacture of comminuted meat products.

Label-free, all-optical detection, imaging, and tracking of a single protein.

Optical detection of individual proteins requires fluorescent labeling. Cavity and plasmonic methodologies enhance single molecule signatures in the absence of any labels but have struggled to demonstrate routine and quantitative single protein detection. Here, we used interferometric scattering microscopy not only to detect but also to image and nanometrically track the motion of single myosin 5a heavy meromyosin molecules without the use of labels or any nanoscopic amplification. Together with the simple experimental arrangement, an intrinsic independence from strong electronic transition dipoles and a detection limit of <60 kDa, our approach paves the way toward nonresonant, label-free sensing and imaging of nanoscopic objects down to the single protein level.

High hydrostatic pressure/temperature modeling of frankfurter batters.

The impact of high pressure/temperature treatment on structure modification and functional sensory properties of frankfurter batter was investigated. The degree of solubilization of meat proteins, particularly of myosin, was identified as a key process with significant effect on the batter's structural properties. The maximal solubilization level was at 200 MPa/40 °C IT for all formulations which was found to be treatment time dependent. The impact of the pressurizing gradient - PG=40 MPa/s and PG=2.5 MPa/s was investigated and estimated to have a significant effect on the protein network and functional properties, respectively. These were improved at low PG (2.5 MPa/s) as a phenomenon of secondary network formation parallel to the main matrix. Batter secondary-structure characteristics were found to be ionic-strength dependent. According to SDS-PAGE analysis, the major role in the solubilization, aggregation and gelation processes occurring in the aqueous phase was due to the myosin S-1 and S-2, N-terminal, C-terminals, the MLC and actin during the high pressure/temperature treatment.

The Qdot-labeled actin super-resolution motility assay measures low-duty cycle muscle myosin step size.

Myosin powers contraction in heart and skeletal muscle and is a leading target for mutations implicated in inheritable muscle diseases. During contraction, myosin transduces ATP free energy into the work of muscle shortening against resisting force. Muscle shortening involves relative sliding of myosin and actin filaments. Skeletal actin filaments were fluorescently labeled with a streptavidin conjugate quantum dot (Qdot) binding biotin-phalloidin on actin. Single Qdots were imaged in time with total internal reflection fluorescence microscopy and then spatially localized to 1-3 nm using a super-resolution algorithm as they translated with actin over a surface coated with skeletal heavy meromyosin (sHMM) or full-length ß-cardiac myosin (MYH7). The average Qdot-actin velocity matches measurements with rhodamine-phalloidin-labeled actin. The sHMM Qdot-actin velocity histogram contains low-velocity events corresponding to actin translation in quantized steps of ~5 nm. The MYH7 velocity histogram has quantized steps at 3 and 8 nm in addition to 5 nm and larger compliance compared to that of sHMM depending on the MYH7 surface concentration. Low-duty cycle skeletal and cardiac myosin present challenges for a single-molecule assay because actomyosin dissociates quickly and the freely moving element diffuses away. The in vitro motility assay has modestly more actomyosin interactions, and methylcellulose inhibited diffusion to sustain the complex while preserving a subset of encounters that do not overlap in time on a single actin filament. A single myosin step is isolated in time and space and then characterized using super-resolution. The approach provides a quick, quantitative, and inexpensive step size measurement for low-duty cycle muscle myosin.

Characterization of myosin subfragment-1 of summer and winter silver carp (Hypophthalmichthys molitrix) muscle.

UNLABELLED: Myosin subfragment-1 (S1) was prepared from myofibrils of summer and winter silver carp by chymotryptic digestion in the presence of ethylenediaminetetraacetic acid (EDTA). Two S1 heavy chain isoforms with different molecular sizes of 91 kDa and 95 kDa were detected in the fast skeletal muscle from summer and winter silver carp, respectively. ATPase inactivation assay indicated that winter S1 was about 20-fold unstable comparing to summer S1. Matrix-assisted laser desorption/ionization time-of-flight/mass spectrometry (MALDI-TOF MS) further confirmed that summer and winter myosin S1 heavy chain isoforms were homologous to myosin high-temperature type and myosin low-temperature type S1 heavy chain, respectively. Moreover, both types of myosin S1 heavy chain isoforms were identified at the intermediate stage. The results indicated that myosin was expressed in a season-specific manner; different types of myosin isomer expressed in different seasons, showing different thermostabilities. PRACTICAL APPLICATION: Silver carp, Hypophthalmichthys molitrix, is one of the most abundant freshwater fish species in China. The structure thermal stability of myosin rod from silver carp was affected by season change. The gel-forming abilities of surimi prepared in different seasons were different. This study investigated the seasonal differences in structure thermal stability of myosin S1 which is vital for gel formation of myosin. The results of this study will aid understanding of the relationship between the structure and function of myosin, and effective production of surimi from freshwater fish species in different seasons.

Characterization of metal and trace element contents of particulate matter (PM10) emitted by vehicles running on Brazilian fuels-hydrated ethanol and gasoline with 22% of anhydrous ethanol.

Emission of fine particles by mobile sources has been a matter of great concern due to its potential risk both to human health and the environment. Although there is no evidence that one sole component may be responsible for the adverse health outcomes, it is postulated that the metal particle content is one of the most important factors, mainly in relation to oxidative stress. Data concerning the amount and type of metal particles emitted by automotive vehicles using Brazilian fuels are limited. The aim of this study was to identify inhalable particles (PM(10)) and their trace metal content in two light-duty vehicles where one was fueled with ethanol while the other was fueled with gasoline mixed with 22% of anhydrous ethanol (gasohol); these engines were tested on a chassis dynamometer. The elementary composition of the samples was evaluated by the particle-induced x-ray emission technique. The experiment showed that total emission factors ranged from 2.5 to 11.8 mg/km in the gasohol vehicle, and from 1.2 to 3 mg/km in the ethanol vehicle. The majority of particles emitted were in the fine fraction (PM(2.5)), in which Al, Si, Ca, and Fe corresponded to 80% of the total weight. PM(10) emissions from the ethanol vehicle were about threefold lower than those of gasohol. The elevated amount of fine particulate matter is an aggravating factor, considering that these particles, and consequently associated metals, readily penetrate deeply into the respiratory tract, producing damage to lungs and other tissues.

Grafting of poly(ethylene glycol) onto poly(acrylic acid)-coated glass for a protein-resistant surface.

The surface of solid glass supports for samples in optical microscopy and for biosensors needs to be protein-resistant. A coating of a poly(ethylene glycol) monomethyl ether (mPEG) on the surface of the glass is one promising method for preventing the nonspecific adsorption of proteins. In this study, we have developed a novel technique for achieving an optimal coverage of a glass surface with mPEG to prevent protein adhesion. A clean glass substrate previously treated with (3-aminopropyl)dimethylethoxysilane (APDMES) was treated sequentially with poly(acrylic acid) and subsequently a primary amine derivative of mPEG in the presence of 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide. The resultant glass surface was demonstrated to be highly protein-resistant, and the adsorption of bovine serum albumin decreased to only a few percentage points of that on a glass surface treated with APDMES alone. Furthermore, to extend the present method, we also prepared a glass substrate on which biotinylated poly(ethylene glycol) was cografted with mPEG, and biotinylated myosin subfragment-1 (biotin-S1) was subsequently immobilized on this substrate by biotin/avidin chemistry. Actin filaments were observed to glide on the biotin-S1-coated glass surface in the presence of ATP, and thus, the method is capable of immobilizing the protein specifically without any loss in its biological function.

Internal motility in stiffening actin-myosin networks.

We present a study on filamentous actin solutions containing heavy meromyosin subfragments of myosin II motor molecules. We focus on the viscoelastic phase behavior and internal dynamics of such networks during adenosine-triphosphate depletion. By combining microrheology and fluorescence microscopy, we observed a sol-gel transition accompanied by a sudden onset of directed filament motion. We interpret the sol-gel transition in terms of myosin II enzymology, and suggest a "zipping" mechanism to explain the filament motion in the vicinity of the sol-gel transition.

A flash photolysis fluorescence/light scattering apparatus for use with sub microgram quantities of muscle proteins.

Transient kinetic methods such as stopped flow and quenched flow have been used to elucidate many of the fundamental features of the molecular interactions which underlie muscle contraction. However, these methods traditionally require relatively large amounts of protein (10(-3) g) and so have been used most effectively for the proteins purified from bulk muscle tissue of large animals or where the proteins can be expressed in large amounts (e.g.. Dictyostelium). We have investigated the use of flash photolysis of an inert precursor of ATP (cATP) to initiate the dissociation of acto.S1 and acto.myosin and the subsequent ATP turnover reaction. Using a sample volume of 10 microl we show that a significant amount of information on the transient and steady-state kinetics of the system can be obtained from a sample containing just 50 nM of acto.myosin or acto.S1 complex in solution. Therefore in presence of excess of one protein component the measurements require only 250 ng myosin, 62 ng S1 or 25 ng actin. This is therefore the method of choice for kinetic analysis of acto.myosins which are only available in microgram quantities. We report for the first time the determination of the second order rate constant of ATP-induced dissociation of actin from the myosin extracted from a single fibre from a rabbit psoas muscle.

A role for C-protein in the regulation of contraction and intracellular Ca2+ in intact rat ventricular myocytes.

1. C-protein is a major component of muscle thick filaments whose function is unknown. We have examined for the first time the role of the regulatory binding domain of C-protein in modulating contraction and intracellular Ca2+ concentration ([Ca2+]i) in intact cardiac myocytes. 2. Rat ventricular myocytes were reversibly permeabilised with the pore-forming toxin streptolysin O. Myosin S2 (which binds to the regulatory domain of C-protein) was introduced into cells during permeabilisation to compete with the endogenous C-protein-thick filament interaction. 3. Introduction of S2 into myocytes increased contractility by approximately 30%, significantly lengthened the time to peak of the contraction and the time to half-relaxation, but had no effect on [Ca2+]i transient amplitude. 4. Our data are consistent with increased myofilament Ca2+ sensitivity when there is reduced binding of C-protein to myosin near the head-tail junction. 5. We propose that the effects of introducing S2 into intact cardiac cells can be equated with the consequences of selectively phosphorylating C-protein in vivo, and that the regulation of contraction by C-protein is mediated by the effects of crossbridge cycling on the Ca2+ affinity of troponin C.

Synthesis and characterization of novel spin-labeled photoaffinity nonnucleoside analogues of ATP as structural and EPR probes for myosin.

Two new spin-labeled photoreactive nonnucleoside ATP analogues, 1-(4-azido-2-nitrophenyl)amino-3-(1-oxyl-2,2,5, 5-tetramethylpyrrolidinyl-3-carbamido)-2-propyl triphosphate (SL-NANTP) and 2-(4-azido-2-nitrophenyl)amino-2,2-(1-oxyl-2,2,6, 6-tetramethyl-4-piperidylidene)di(oxymethylene) ethyl triphosphate (SSL-NANTP), were synthesized and characterized. This study aims to develop a second generation of NANTP-based analogues containing immobile spin labels that can be used to monitor conformational changes in myosin during the contractile cycle of muscle. Previous studies have shown that both a photoaffinity nonnucleoside ATP analogue, 2-[(4-azido-2-nitrophenyl)amino] ethyl triphosphate (NANTP) [Nakamaye et al. (1985) Biochemistry 24, 5226-5235], and a photoaffinity ATP analogue, 3'(2')-O-4-[4-oxo-(4-amino-2,2,6, 6-tetramethyl-piperidino-1-oxyl)-4-benzoyl] benzoyl adenosine 5'-triphosphate (SL-Bz(2)ATP) [Wang et al. (1999) J. Muscle Res. Cell Motil. 20, 743-753], behave like ATP in their interactions with myosin. Remarkably, photolabeled myosin recovers all of its normal enzymatic properties after treatment with actin in the presence of MgATP [Luo et al. (1995) Biochemistry 34, 1978-1987]. For SL-NANTP, the spin label moiety is attached to NANTP via an aminomethyl side chain. In SSL-NANTP, attachment is via a restricted spiro ring. The two new probes interact with myosin subfragment-1 (S1) in a manner analogous to ATP, and after photoincorporation, labeled S1 recovers full activity after treatment with actin and MgATP. The electron paramagnetic resonance (EPR) spectrum resulting from S1 photolabeled with SL-NANTP shows a very high degree of probe mobility. However, the EPR spectrum of S1 photolabeled with SSL-NANTP shows that the probe is highly immobilized with respect to S1, constrained to move within a cone of angle 52 degrees (full-width, half-max). Unlike the parent, NANTP, which photolabels on the 23 kDa tryptic fragment of S1, SSL-NANTP photolabels on the 20 kDa fragment. Its highly immobile nature means that it is potentially a useful reporter group to monitor cross-bridge motion in muscle fibers.

Native purification of biomolecules with temperature-mediated hydrophobic modulation liquid chromatography.

The high-resolution purification of native enzymes is impeded by the limitations in the mobile-phase choices required for conventional hydrophobic separations such as in reverse-phase chromatography. To avoid problems associated with varying the composition of the mobile phase, we developed a stationary phase with a hydrophobicity that can be modulated by slight variations in temperature to bind and elute biomolecules. This chromatographic matrix was tested on nucleotide analogs, amino acids, and protein samples. Visualization of the temperature-dependent hydrophobic interaction with the chromatographic matrix was performed with fluorescence microscopy of CY3-ATP. Amino acids adsorbed to the column according to their known hydrophobicities, confirming the hydrophobic nature of their interaction with the matrix. Biomolecules were separated by modulating the hydrophobicity of the column matrix with slight adjustments to the running temperature between 22 and 37 degrees C without changing the mobile phase. Freedom in the choice of a mobile phase for both the loading and the elution of samples provides great practical advantages by eliminating the need for buffer-exchange steps and allowing more native conditions for purifying delicate enzymes, such as myosin.

Speeds of actin translocation in vitro by myosins extracted from single rat muscle fibres of different types.

As skeletal muscle fibres mostly express a single myosin isoform, they are a potential source of pure myosin isoforms. A technique is described that allows extraction and identification of pure myosin isoforms from single fibres, and testing of such myosins in an in vitro motility assay (IVMA). The results show that the extraction procedure does not alter myosin function and support the view that single fibres are reliable sources of purified myosin isoforms for IVMA.

Modulation of the differentiation status of cultured prostatic smooth muscle cells by an alpha1-adrenergic receptor antagonist.

BACKGROUND: Prostatic stromal cells are believed to be a key factor in the pathogenesis of benign prostatic hyperplasia (BPH). The effect of phenylephrine, an alpha1-adrenergic receptor agonist, and doxazosin, an alpha1-adrenergic receptor-specific antagonist, on the expression of smooth muscle myosin-heavy-chain isotypes SM-1 and SM-2 was tested in an in vitro model of prostatic smooth muscle cells (SMC). METHODS: Primary prostatic stromal cells, grown in SMC-specific medium, were treated with 10 microM of phenylephrine or 1 microM of doxazosin or a combination of both. SM-2 to SM-1 mRNA ratios and expression of alpha1-adrenergic receptor subtypes were determined by means of reverse transcriptase polymerase chain reaction (RT-PCR) techniques. Cell growth was measured by a cell viability assay. RESULTS: SM-1 mRNA and only very low levels of SM-2 mRNA were detected in prostatic SMC cultures grown for 4 days in a serum-free base medium. After 6 days of treatment, SM-2 expression increased, highest in the doxazosin-treated cultures. In comparison to unstimulated cells, a statistically significant 10-fold increase of the SM-2:SM-1 ratio was measured in doxazosin-treated cultures. Analysis of alpha1-adrenergic receptor subtype expression revealed the presence of mRNAs of subtypes 1d and 1b mRNAs. Subtype 1a was not expressed. Phenylephrine and doxazosin showed no significant effect on cell proliferation and on alpha1d-adrenergic receptor expression. CONCLUSIONS: SMC can differentiate from a proliferative to a contractile phenotype, which is accompanied by increased expression of isotope 2 of smooth muscle myosin heavy chain. Our results suggest that doxazosin seems to have a long-term effect on the differentiation of prostatic stromal cells, indicating that alpha1-adrenergic receptor antagonists do not act solely on SMC contractility.

Localization of cytoskeletal filaments during membrane rearrangement in rat parietal cells stimulated with gastrin.

When stomachs are stimulated to secrete acid, the intracellular canaliculi of the parietal cell increase and there is a concomitant depletion of the cytoplasmic tubulovesicular system. This change is believed to occur through the transformation of tubulovesicular membranes into intracellular canaliculi. This study was undertaken to examine the distribution of the cytoskeletons in rat gastric parietal cells during this process. In the resting parietal cells, actin filaments decorated with heavy meromyosin (HMM) were found in the cores of microvilli, extending from the apex of microvilli into the pericanalicular cytoplasm and forming radial networks. In some cases, these actin filaments were also associated with the tubulovesicles. Moreover, tubulovesicular membranes were rare in the 300 nm zone around intracellular canaliculi but numerous actin filaments were seen in this region. Soon after stimulation of the parietal cells by gastrin, tubulovesicles were closely associated with the intracellular canaliculi, while actin filaments networks adjacent to the canaliculi diminished and their labeling with HMM seemed less orderly. By immunocytochemistry, immunogold particles indicating ezrin were associated with microvillous membranes in the resting as well as stimulated parietal cells but were absent on the tubulovesicular membranes. When intermediate filaments were immunocytochemically investigated using anti-cytokeratin immunogold particles clearly labeled filamentous bundles present around the intracellular canaliculi, perinuclear spaces and under the basolateral cell membrane. Their localization was not changed after stimulation. These results suggest that actin filaments in the cytoplasm around the intracellular canaliculi may play a key role in the translocation of the tubulovesicles toward the intracellular canaliculi during the acid secreting process.

Evidence that the tandem Ig domains near the end of the muscle thick filament form an inelastic part of the I-band titin.

In vertebrate striated muscle the titin/connectin molecule spans half a sarcomere, and in the I-band forms and elastic filament connecting the Z-line with the end of the thick filaments. The only part of the elastic filament that has been described in intact rest length muscle is a short extension to the thick filament observed in freeze-fractured cardiac muscle which has similarities to the end-filament of negatively stained isolated thick filaments. We report here further observations made in sections of rabbit psoas muscle. In very thin longitudinal sections thin extensions to the thick filaments some 0.11 micron long and 5-6 nm in diameter are seen. Transverse sections show that each thick filament has such an extension. Nothing similar is seen further into the I-band or at the Z-line. The common features of this structure in both cardiac and skeletal muscle suggest that it corresponds to a common sequence in their titins. Such a sequence is to be found in the 22 tandem Ig domains near the A/I junction. Taken together with other information about the arrangement of domains in this part of the sarcomere, this leads to a calculated length for the end extension of 104 nm. The length of the extension does not vary with sarcomere length between 2.2 and 3.0 microns and therefore it corresponds to an inelastic region of I-band titin over the physiological range. Each extension probably comprises part of three to six titin molecules depending on the complement of titin in the thick filament, as previously suggested. A polymer formed from several strands of Ig domains would make for a relatively rigid structure which would resist folding or stretching when subjected to the small passive forces which pertain over the physiological range of sarcomere lengths. The relationship of the N2-line with the end-filament has also been studied. The N2-line position varies with sarcomere length in an elastic manner. Only at short sarcomere lengths does the end of the end-filament coincide with the position of the N2-line. Taking into account recent work on the elasticity of titin in the I-band we conclude that the N2-line corresponds to part of the elastic PEVK region of titin and not the region of titin sequence designated N2.

Identification of atrial-specific myosin heavy chain in cardiac muscle of adult chickens.

The partial amino acid sequence of subfragment-1 of adult chicken atrial myosin was determined by direct protein sequencing. Subfragment-1 was prepared by limited digestion of adult chicken atrial myosin with alpha-chymotrypsin. Ten peptides were then obtained by cleaving this subfragment with cyanogen bromide. The amino acid composition and amino acid sequence of the obtained peptides were subsequently determined. By sequence comparison with the corresponding region of adult chicken ventricular myosin, three peptides, with differing sequences that corresponded to the same position in subfragment-1, were detected. This indicates that at least three isoforms of atrial myosin exist in adult chicken atrial muscle. One of the three peptides was identical to ventricular subfragment-1 while the remaining two peptides were markedly different. Furthermore, four of these ten peptides were completely different from ventricular subfragment-1. These four peptides were presumed to be fragments of atrial-specific myosin heavy chain protein. Results suggest the expression of at least two species of atrial-specific myosin heavy chain in the atrial muscle of adult chickens.

Equilibration and exchange of fluorescently labeled molecules in skinned skeletal muscle fibers visualized by confocal microscopy.

Confocal laser fluorescence microscopy was used to study in real time under nearly physiological conditions the equilibration and exchange characteristics of several different fluorescently labeled molecules into chemically skinned, unfixed skeletal muscle fibers of rabbit psoas. The time required for equilibration was found to vary widely from a few minutes up to several days. Specific interactions of molecules with myofibrillar structures seem to slow down equilibration significantly. Time for equilibration, therefore, cannot simply be predicted from diffusion parameters in solution. Specific interactions resulted in characteristic labeling patterns for molecules like creatine kinase (muscle type), pyruvate kinase, actin-binding IgG, and others. For the very slowly equilibrating Rh-NEM-S1, changes in affinity upon binding to actin in the absence of calcium and subsequent slow cooperative activation, beginning at the free end of the filament at the H-zone, were observed. In the presence of calcium, however, binding of Rh-NEM-S1 was homogeneous along the whole actin filament from the very beginning of equilibration. The dissociation properties of the dynamic interactions were analyzed using a chase protocol. Even molecules that bind with rather high affinity and that can be removed only by applying extreme experimental conditions like Rh-phalloidine or Rh-troponin could be displaced easily by unlabeled homologous molecules.