Promoter analysis of a growth hormone transgene in Atlantic salmon.

The ocean pout (Macrozoarces americanus) op5a antifreeze protein gene promoter has been used to generate a line of growth hormone (GH) transgenic Atlantic salmon with greatly enhanced growth rates. A study of the genomically integrated GH transgene (EO-1 alpha) in this line of salmon revealed that the first 1579 bp of the 2115-bp promoter was deleted and relocated downstream of the GH coding region, raising questions regarding the ability of the truncated promoter to drive expression of the GH transgene and the potential influence of the relocated 5' promoter region. In this study, 11 promoter constructs were fused to a luciferase reporter gene, and their transcriptional ability was examined after transfection into salmon and human cell lines cultured at 21 and 37 degrees C, respectively. Construct expression was similar in all cell lines, apart from those of less than 266 bp, where expression in the salmon cells greatly exceeded that of the human cells. The results demonstrated the presence of positive and negative regulatory regions within the promoter that would allow the regulation of gene expression at multiple sites. Removal of the first 1579 bp from the promoter resulted in a 70% loss of the luciferase expression exhibited by the full-length promoter, whereas ligating the deleted 5' promoter sequence downstream of the luciferase reporter gene only restored approximately 10% of this loss. These results suggested that in vivo expression of the EO-1 alpha transgene is driven by elements within the weak truncated promoter in conjunction with the relocated 5' promoter region.

Atmospheric oxidation capacity sustained by a tropical forest.

Terrestrial vegetation, especially tropical rain forest, releases vast quantities of volatile organic compounds (VOCs) to the atmosphere, which are removed by oxidation reactions and deposition of reaction products. The oxidation is mainly initiated by hydroxyl radicals (OH), primarily formed through the photodissociation of ozone. Previously it was thought that, in unpolluted air, biogenic VOCs deplete OH and reduce the atmospheric oxidation capacity. Conversely, in polluted air VOC oxidation leads to noxious oxidant build-up by the catalytic action of nitrogen oxides (NO(x) = NO + NO2). Here we report aircraft measurements of atmospheric trace gases performed over the pristine Amazon forest. Our data reveal unexpectedly high OH concentrations. We propose that natural VOC oxidation, notably of isoprene, recycles OH efficiently in low-NO(x) air through reactions of organic peroxy radicals. Computations with an atmospheric chemistry model and the results of laboratory experiments suggest that an OH recycling efficiency of 40-80 per cent in isoprene oxidation may be able to explain the high OH levels we observed in the field. Although further laboratory studies are necessary to explore the chemical mechanism responsible for OH recycling in more detail, our results demonstrate that the biosphere maintains a remarkable balance with the atmospheric environment.

Phenomenological evidence for two types of paranoia.

OBJECTIVE: Two types of paranoia have been identified, namely persecution (or 'Poor Me') paranoia, and punishment (or 'Bad Me') paranoia. This research tests predicted differences in phenomenology--specifically, in person evaluative beliefs, self-esteem, depression, anxiety, and anger. METHOD: Fifty-three people with current paranoid beliefs were classified as Poor Me, Bad Me, or neither (classification was reliable). Key dependent variables were measured. RESULTS: All predictions were supported, except the one relating to anger, where the two groups did not differ. The Bad Me group had lower self-esteem, more negative self-evaluative thinking, lower negative evaluations about others, higher depression and anxiety. Importantly, the differences in self-esteem and self-evaluations were not fully accounted for by differences in depression. CONCLUSION: Data support the presence of two distinct topographies of paranoia. Future research is needed to explore the theory further and examine clinical implications.

White monkey syndrome in infant baboons (Papio species).

Over 23 months, zinc toxicosis was diagnosed in 35 baboons aged 5-12 months in one galvanized metal and concrete cage complex with conditions that led to excessive exposure to environmental zinc. Clinical signs included reduced pigmentation of hair, skin, and mucous membranes (whiteness), alopecia, dehydration, emaciation, cachexia, dermatitis, diarrhea and, in six cases, severe gangrenous dermatitis of extremities. The syndrome was characterized by pancytopenia, elevated zinc and low copper serum concentrations, low vitamin D and bone-specific alkaline phosphatase levels, and atypical myelomonocytic proliferation of bone marrow. This syndrome emphasizes the importance of proper husbandry and cage design and indicates the potential of infant baboons as a model to study the effects of excessive zinc on development. This is the first report describing the epidemiologic and clinical presentation of zinc toxicosis in infant baboons in captivity.

Relaxant effects of parathyroid hormone and parathyroid hormone-related peptides on oviduct motility in birds and mammals: possible role of nitric oxide.

Parathyroid hormone (PTH) and PTH-related peptides (PTHrP) have previously been shown to modulate the contractile state of numerous types of smooth muscle. The effects of N-terminal PTH and PTHrP on spontaneous in vitro contractility of oviducal smooth muscle using tissues from egg-laying Japanese quail (10-15 h post ovulation), 4 and 9 days pregnant mouse uterus were investigated. Myometrial tissues from both species contracted vigorously for several hours, when incubated in organ baths in De Jalon's solution gassed with 5%CO2/95%O2. Contractions were enhanced in high (1.2-2.5 mM) compared with low (0.1-0.5 mM) calcium (Ca) containing media. Bovine PTH(1-34) (bPTH(1-34)), human PTH(1-34 amide) (hPTHrP(1-34) amide), and hPTHrP(1-40) caused similar concentration-related inhibition of contractions in media containing 1.2mM Ca over a range of 10(-9) to 10(-7)M, whereas C-terminal hPTHrP(107-139) was devoid of such activity. Responses to bPTH(1-34) in 4 and 9-day pregnant mouse tissues were similar but hPTHrP(1-40) showed substantial loss of activity in 9-day, compared with 4-day pregnant mouse tissues. Repeated exposure of mouse uterine tissue to the peptides resulted in desensitisation of responses. The EC50 responses of mouse tissues were inhibited by the PTH/PTHrP receptor antagonist, hPTHrP(7-34) amide. Responses to bPTH(1-34) were also inhibited by both non-selective and selective neuronal nitric oxide synthase (NOS) inhibitors N(omega)-nitro-L-arginine methyl ester (0.01-1mM) and 7-nitroindazole (0.01-10 microM), respectively. Both NOS inhibitors were more effective in inhibiting bPTH(1-34)-induced relaxation in the absence of L-arginine compared with in the presence of 1mM L-arginine (a NOS substrate) in the incubation media. It is concluded that relaxant responses to N-terminal PTH and PTHrP peptides are well conserved in oviducal and uterine tissues from avian and mammalian species. The results also suggest that NO may be responsible for mediating relaxant activities of these peptides in pregnant mouse uterine tissue.

Phosphorylation of molluscan twitchin by the cAMP-dependent protein kinase.

Catch in certain molluscan muscles is released by an increase in cAMP, and it was suggested that the target of cAMP-dependent protein kinase (PKA) is the high molecular weight protein twitchin [Siegman, M. J., Funabara, J., Kinoshita, S., Watabe, S., Hartshorne, D. J., and Butler, T. M. (1998) Proc. Natl. Acad. Sci. U.S.A. 95, 5384-5388]. This study was carried out to investigate the phosphorylation of twitchin by PKA. Twitchin was isolated from Mytilus catch muscles and was phosphorylated by PKA to a stoichiometry of about 3 mol of P/mol of twitchin. There was no evidence of twitchin autophosphorylation. Two phosphorylated peptides were isolated and sequenced, termed D1 and D2. Additional cDNA sequence for twitchin was obtained, and the D2 site was located at the C-terminal side of the putative kinase domain in a linker region between two immunoglobulin C2 repeats. Excess PKA substrates, e.g., D1 and D2, blocked the reduction in force on addition of cAMP, confirming the role for PKA in regulating catch. Papain proteolysis of (32)P-labeled twitchin from permeabilized muscles showed that the D1 site represented about 50% of the (32)P labeling. Proteolysis of in-situ twitchin with thermolysin suggested that the D1 and D2 sites were at the N- and C-terminal ends of the molecule, respectively. Thermolysin proteolysis also indicated that D1 and D2 were major sites of phosphorylation by PKA. The direct phosphorylation of twitchin by PKA is consistent with a regulatory role for twitchin in the catch mechanism and probably involves phosphorylation at the D1 and D2 sites.

Age-related autoantibody production in a nonhuman primate model.

Autoantibody production increases with ageing. However, the pathological significance of this increase as well as the corresponding underlying mechanisms are poorly understood. To further our understanding of the role that ageing plays in the development of autoantibody responses, we used a novel nonhuman primate model consisting of healthy baboons of ages representing the entire lifespan of this animal species. Results from this study indicate that production of antinuclear antibodies, anticell extract antibodies and natural autoantibodies gradually and significantly increases from young age to old age without a corresponding increase in neither serum immunoglobulin concentration nor in levels of selected markers of immune dysregulation (sTNF-RI, sTNF-RII, IL-2 sR alpha and IFN-gamma). Therefore, in the baboon model, autoantibodies may be produced in absence of recognizable pathological conditions of the ageing immune system.

The myosin cross-bridge cycle and its control by twitchin phosphorylation in catch muscle.

The anterior byssus retractor muscle of Mytilus edulis was used to characterize the myosin cross-bridge during catch, a state of tonic force maintenance with a very low rate of energy utilization. Addition of MgATP to permeabilized muscles in high force rigor at pCa > 8 results in a rapid loss of some force followed by a very slow rate of relaxation that is characteristic of catch. The fast component is slowed 3-4-fold in the presence of 1 mM MgADP, but the distribution between the fast and slow (catch) components is not dependent on [MgADP]. Phosphorylation of twitchin results in loss of the catch component. Fewer than 4% of the myosin heads have ADP bound in rigor, and the time course (0.2-10 s) of ADP formation following release of ATP from caged ATP is similar whether or not twitchin is phosphorylated. This suggests that MgATP binding to the cross-bridge and subsequent splitting are independent of twitchin phosphorylation, but detachment occurs only if twitchin is phosphorylated. A similar dependence of detachment on twitchin phosphorylation is seen with AMP-PNP and ATPgammaS. Single turnover experiments on bound ADP suggest an increase in the rate of release of ADP from the cross-bridge when catch is released by phosphorylation of twitchin. Low [Ca(2+)] and unphosphorylated twitchin appear to cause catch by 1) markedly slowing ADP release from attached cross-bridges and 2) preventing detachment following ATP binding to the rigor cross-bridge.

Mycobacterium tuberculosis-secreted protein antigens: immunogenicity in baboons.

The effective control of tuberculosis (TB) requires the development of improved vaccines. It is now well established that Mycobacterium tuberculosis-secreted antigens represent promising candidates to be included in subunit vaccine preparations. It also is accepted that studies in nonhuman primate models will be required to further develop these vaccine preparations. As a necessary step in this direction, we have assessed the immunogenicity of M. tuberculosis-secreted antigens in baboons. Animals received a total of three intramuscular injections consisting of M. tuberculosis culture filtrate proteins resuspended in an adjuvant formulation (MPL-SE) and were tested for development of specific antibody and cellular responses. All animals produced antibody and cellular proliferative responses in the absence of detectable delayed-type hypersensitivity reactions. Production of gamma-interferon following stimulation of peripheral blood lymphocytes with culture filtrate proteins was either absent or present at low levels. Results from this study show that, although M. tuberculosis-secreted protein antigens are relatively safe and immunogenic in baboons, alternative immunization approaches must be identified for the induction of T-helper type 1 responses.

Integrated optical Bragg-grating-based chemical sensor on a curved input edge waveguide structure.

A novel integrated optical chemical sensor based on a surface-relief Bragg grating in a waveguide with a curved input edge, and coated with a chemically sensitive polysiloxane cladding, is described. The curved edge provides a mechanism within the device fabrication that allows for alignment of the input beam to the grating to achieve Bragg scattering. As proof of principle, a low-parts-in-10(6) toluene-vapor sensor with a fast response time is demonstrated.

Regulation of catch muscle by twitchin phosphorylation: effects on force, ATPase, and shortening.

Recent experiments on permeabilized anterior byssus retractor muscle (ABRM) of Mytilus edulis have shown that phosphorylation of twitchin releases catch force at pCa > 8 and decreases force at suprabasal but submaximum [Ca2+]. Twitchin phosphorylation decreases force with no detectable change in ATPase activity, and thus increases the energy cost of force maintenance at subsaturating [Ca2+]. Similarly, twitchin phosphorylation causes no change in unloaded shortening velocity (Vo) at any [Ca2+], but when compared at equal submaximum forces, there is a higher Vo when twitchin is phosphorylated. During calcium activation, the force-maintaining structure controlled by twitchin phosphorylation adjusts to a 30% Lo release to maintain force at the shorter length. The data suggest that during both catch and calcium-mediated submaximum contractions, twitchin phosphorylation removes a structure that maintains force with a very low ATPase, but which can slowly cycle during submaximum calcium activation. A quantitative cross-bridge model of catch is presented that is based on modifications of the Hai and Murphy (1988. Am. J. Physiol. 254:C99-C106) latch bridge model for regulation of mammalian smooth muscle.

Phosphorylation of a twitchin-related protein controls catch and calcium sensitivity of force production in invertebrate smooth muscle.

"Catch" is a condition of prolonged, high-force maintenance at resting intracellular Ca2+ concentration ([Ca2+]) and very low energy usage, occurring in invertebrate smooth muscles, including the anterior byssus retractor muscle (ABRM) of Mytilus edulis. Relaxation from catch is rapid on serotonergic nerve stimulation in intact muscles and application of cAMP in permeabilized muscles. This release of catch occurs by protein kinase A-mediated phosphorylation of a high (approximately 600 kDa) molecular mass protein, the regulator of catch. Here, we identify the catch-regulating protein as a homologue of the mini-titin, twitchin, based on (i) a partial cDNA of the purified isolated protein showing 77% amino acid sequence identity to the kinase domain of Aplysia californica twitchin; (ii) a polyclonal antibody to a synthetic peptide in this sequence reacting with the phosphorylated catch-regulating protein band from permeabilized ABRM; and (iii) the similarity of the amino acid composition and molecular weight of the protein to twitchin. In permeabilized ABRM, at all but maximum [Ca2+], phosphorylation of twitchin results in a decreased calcium sensitivity of force production (half-maximum at 2.5 vs. 1.3 microM calcium). At a given submaximal force, with equal numbers of force generators, twitchin phosphorylation increased unloaded shortening velocity approximately 2-fold. These data suggest that aspects of the catch state exist not only at resting [Ca2+], but also at higher submaximal [Ca2+]. The mechanism that gives rise to force maintenance in catch probably operates together, to some extent, with that of cycling myosin crossbridges.

Clinical disease associated with simian agent 8 infection in the baboon.

Simian agent 8 (SA8) is an alphaherpesvirus that was first reported as a spontaneous natural infection in a captive baboon colony in 1988. It was first isolated from an African vervet monkey in 1958 and was classified as a simian agent. Simian agent 8 was later isolated from a baboon rectal swab specimen in 1969 and from an oral lesion in a vervet monkey in 1972. Restriction endonuclease analysis was used to identify the virus as SA8. In a 1-year period, 70 baboons housed in two outside 6-acre breeding corrals developed lesions principally on the genitalia and oral cavity. The incidence was the same for males and females, with recurrence rate, severity of the lesions, and duration for the lesions to resolve being greater in the female baboons. Lesions involving the mouth, tongue, and lips were most commonly observed in the juvenile population. The lesions tended to start as small multiple papules or vesicles, which advanced to large pustular or ulcerative areas. Using an every-other-day treatment regimen consisting of Nolvasan cleaning and procaine penicillin G injections, it took an average of 14 to 21 days for the lesions to resolve totally. Thirty-seven percent of the baboons with herpetic lesions experienced another episode of SA8 infection, usually within 1 year of development of the primary lesion. Several complications have been documented to be associated with SA8 infections. Partial or total vaginal obstruction is most common, leading to impaired breeding performance and pyelonephritis. A vaginal corrective surgical procedure has been developed to allow these females to return to productive breeding status within the colony. Penile urethral obstruction, also causing pyelonephritis, was observed in the male baboons. A case of sciatic neuritis was reported in a baboon that presented with self mutilation of the foot; viral isolation revealed the etiologic agent to be SA8. Four female baboons with chronic SA8 infections went on to develop perineal neoplasms. This is an economically important disease entity in captive baboons because it causes severe morbidity, decreased reproductive performance, and ultimately death in 1% of the baboon colony each year. The baboon is a promising animal model in which to study genital herpes as it relates to disease in human beings.

Control of cross-bridge cycling by myosin light chain phosphorylation in mammalian smooth muscle.

This review focuses on experiments in which the single turnover of myosin-bound ADP is used to characterize the regulation of the cross-bridge cycle by myosin light chain phosphorylation in mammalian smooth muscle. Under isometric conditions, at rest, when the myosin light chain is not phosphorylated, myosin cycles very slowly (about 0.004 s-1), while phosphorylation of the light chain results in a 50-fold increase in cycling rate of 0.2 s-1. Experiments consistently show that some myosin does not increase its cycling rate although its light chain is phosphorylated. Studies at low levels of myosin light chain phosphorylation show that phosphorylation also induces an increase in the cycling rate of unphosphorylated myosin. The fast cycling phosphorylated myosin is the main determinant of suprabasal myosin ATPase activity, while the cycling rate of cooperatively activated unphosphorylated myosin is slow and appears to depend on the extent of phosphorylation of the entire thick filament. Single turnover experiments measuring the rate of phosphorylation and dephosphorylation of myosin light chain show that the turnover of light chain phosphate can be very rapid (0.3-0.4 s-1) at suprabasal calcium concentrations. The expected effect of such a rapid turnover of light chain phosphorylation on the turnover of myosin-bound ADP is not observed. The effects of low levels of myosin light chain phosphorylation on the single turnover of myosin suggest that the same small pool of myosin remains phosphorylated for relatively long periods of time rather than the entire pool of myosin spending a small fraction of its cycle time in the phosphorylated state.

Hypertrophy of colonic smooth muscle: structural remodeling, chemical composition, and force output.

The cellular basis of adaptations occurring during the development of megacolon was studied with the lethal spotted mouse model. Age-dependent changes in the length-force characteristics of the colon reach a steady state by 3-4 mo and include an increased relative force development at very short muscle lengths. In megacolon the following occur: 1) structural remodeling expressed as a greater increase in the fraction of maximum force production at short lengths, a shift of optimum length (Lo) to longer lengths, and no change in force per square centimeter; 2) hypertrophy and hyperplasia of both circular and longitudinal muscle; 3) high resting compliance consistent with no disproportionate change in collagen or elastin composition; 4) marked distension so that in situ circumference approximately 1.8 Lo, where active force production is low, and 5) slack length approximately 0.65 Lo, as in normal colon. Biochemical remodeling in megacolon includes disproportionate increases in ATP and phosphocreatine concentration, with 3.5-fold more preformed phosphagen than in normal colon. The myosin concentration is the same in both muscles, but the actin concentration is 1.5-fold greater in megacolon. Most of the cellular changes in megacolon would facilitate high active force output from the muscle at much larger intestinal diameters.

Hypertrophy of colonic smooth muscle: contractile proteins, shortening velocity, and regulation.

Smooth muscle in megacolon was studied in the lethal spotted mouse and its normal sibling. In megacolon, structural remodeling and a very large increase in total protein content are associated with some changes in the contractile protein isoform composition. 1) There is a higher actin concentration in megacolon, primarily caused by a larger proportion of gamma-isoforms. 2) There was no difference in myosin concentration or in SM1/SM2 heavy chains in megacolon and normal muscle contractile proteins. 3) Only LC17a essential light chain is present in both normal and megacolon. 4) The 25- to 50-kDa 5'-insert occurs in 15-20% of the myosin in normal colon, compared with 5- to 10-fold lower amounts in megacolon. In permeabilized muscles there was no significant difference in unloaded shortening velocity (Vo) with maximal thiophosphorylation of the 20-kDa light chains, nor was there significant difference in the force vs. Ca2+ and force vs. myosin light chain phosphorylation relationships. At approximately 60% myosin light chain phosphorylation after Ca2+ activation, Vo of megacolon was approximately two times faster than Vo of normal muscle. These cellular changes largely account for the higher propulsive velocity of the colon in situ. The distribution of myosin and actin isoforms and the lack of a simple relationship between myosin light chain phosphorylation and Vo point to the operation of additional regulatory processes.

Phosphorylation of a high molecular weight (approximately 600 kDa) protein regulates catch in invertebrate smooth muscle.

A unique property of smooth muscle is its ability to maintain force with a very low expenditure of energy. This characteristic is highly expressed in molluscan smooth muscles, such as the anterior byssus retractor muscle (ABRM) of Mytilus edulis, during a contractile state called 'catch'. Catch occurs following the initial activation of the muscle, and is characterized by prolonged force maintenance in the face of a low [Ca2+]i, high instantaneous stiffness, a very slow cross-bridge cycling rate, and low ATP usage. In the intact muscle, rapid relaxation (release of catch) is initiated by serotonin, and mediated by an increase in cAMP and activation of protein kinase A. We sought to determine which proteins undergo a change in phosphorylation on a time-course that corresponds to the release of catch in permeabilized ABRM. Only one protein consistently satisfied this criterion. This protein, having a molecular weight of approximately 600 kDa and a molar concentration about 30 times lower than the myosin heavy chain, showed an increase in phosphorylation during the release of catch. Under the mechanical conditions studied (rest, activation, catch, and release of catch), changes in phosphorylation of all other proteins, including myosin light chains, myosin heavy chain and paramyosin, are minimal compared with the cAMP-induced phosphorylation of the approximately 600 kDa protein. Under these conditions, somewhat less than one mole of phosphate is incorporated per mole of approximately 600 kDa protein. Inhibition of A kinase blocked both the cAMP-induced increase in phosphorylation of the protein and the release of catch. In addition, irreversible thiophosphorylation of the protein prevented the development of catch. In intact muscle, the degree of phosphorylation of the protein increases significantly when catch is released with serotonin. In muscles pre-treated with serotonin, a net dephosphorylation of the protein occurs when the muscle is subsequently put into catch. We conclude that the phosphorylation state of the approximately 600 kDa protein regulates catch.

Thiophosphorylation of the 130-kDa subunit is associated with a decreased activity of myosin light chain phosphatase in alpha-toxin-permeabilized smooth muscle.

Pretreatment of alpha-toxin-permeabilized smooth muscle with ATP gamma S (adenosine 5'-O-(thiotriphosphate)) under conditions resulting in minimal (< 1%) thiophosphorylation of the myosin light chain increases the subsequent calcium sensitivity of force output and myosin light chain phosphorylation. The change in calcium sensitivity results at least in part from a 5-fold decrease in myosin light chain phosphatase activity. One of the few proteins thiophosphorylated under these conditions is the 130-kDa subunit of myosin light chain phosphatase. These results suggest that thiophosphorylation of this subunit leads to a decrease in the activity of the phosphatase, and that phosphorylation and dephosphorylation of the subunit may play a role in regulating myosin light chain phosphatase activity.

Xenotransplantation.

Transplantation of solid organs (heart, lung, liver, and kidney) from swine to humans would solve the current critical shortage of cadaver organs needed by patients with end-stage disease of these organs. In addition, transplantation between distant species (discordant xenografting) will require an understanding of a number of unique immunologic features. Discordant xenografts are rejected within minutes to hours after transplantation. This rejection is due to natural immunity by recipients never before exposed to the xenografts. In some species combinations, this fulminant rejection is due to naturally occurring pre-existing antibodies against the xenograft endothelium. In other species combinations, the xenograft activates the alternative pathway of complement. The swine to human species combination is the most clinically relevant. In this combination, natural human and private antibodies recognize alpha-galactosyl residues of glycoproteins and glycolipids. Potential future therapeutic measures to prevent natural immunity include the genetic engineering of human complement inhibitors into swine cell membranes or genetic "knock out" of the enzymes responsible for placing alpha-galactosyl residues on swine cell surfaces. There are also special considerations in acquired immunity against xenografts. Cytokines and adhesion molecules may not work across species lines. Xenograft antigens may have to be processed by host antigen-presenting cells in order to effectively stimulate the immune system.

Rapid turnover of myosin light chain phosphate during cross-bridge cycling in smooth muscle.

The rate of phosphatase-mediated dephosphorylation of the regulatory light chain of smooth muscle myosin was determined under nearly steady-state conditions in permeabilized muscles, from the time course of incorporation of 33P-labeled phosphate into the light chain after the photolytic release of [gamma-33P]ATP from high specific activity caged [gamma-33P]ATP. The extent of myosin light chain phosphorylation is unchanged, and, if the kinase and phosphatase reactions are irreversible, the rate constant for the exponential increase in 33P in the light chain is equal to the rate constant for the phosphatase reaction. Under activated conditions (pCa 4.5) at 20 degrees C, the incorporation of 33P into approximately 80% of the phosphorylated light chain is fit by a single exponential with a rate constant of 0.37 s-1. ATP usage due to phosphorylation and dephosphorylation of the light chain is about one-third of the suprabasal energy requirement. The high phosphatase rate constant suggests that dephosphorylation of the light chain is rapid enough to interact with and potentially modify the completion of the cross-bridge cycle.