Robert B. Low

Loss of SM-B myosin affects muscle shortening velocity and maximal force development

We used an exon-specific gene-targeting strategy to generate a mouse model deficient only in the SM-B myosin isoform. Here we show that deletion of exon-5B (specific for SM-B) in the gene for the heavy chain of smooth muscle myosin results in a complete loss of SM-B myosin and switching of splicing to the SM-A isoform, without affecting SM1 and SM2 myosin content. Loss of SM-B myosin does not affect survival or cause any overt smooth muscle pathology. Physiological analysis reveals that absence of SM-B myosin results in a significant decrease in maximal force generation and velocity of shortening in smooth muscle tissues. This is the first in vivo study to demonstrate a functional role for the SM-B myosin isoform. We conclude that the extra seven-residue insert in the surface loop 1 of SM-B myosin is a critical determinant of crossbridge cycling and velocity of shortening.

An ultramicro method of amino acid analyses: Application to studies of protein metabolism in cultured cells

Abstract Analysis of the quantity and specific radioactivity of amino acids derived from intra-cellular pools, aminoacyl-transfer RNA, and protein hydrolysates of cultured cells has been achieved using a radiolabeled amino group ligand, dansyl chloride. Speeific activities of 14 C- or 3 H-labeled amino acids are calculated after reaction with appropriately labeled dansyl chloride of known specific activity. The quantity of amino acid is determined as a function of its diluting influence on a radioactive standard. The specific activity of as little as 2 pmol of amino acid can be measured using [ 14 C]dansyl chloride the less sensitive of the two isotopic species available. Thus, cells from a single 60-mm culture dish provide sufficient material for analysis of both intracellular and transfer RNA amino acid pools, and one can easily analyze the amino acids in hydrolysates made from individual bands in polyacrylamide gels. The method offers significant improvement in speed, sensitivity, and economy over conventional methods of amino acid analysis and, because of its double-label design, gives accurate results with a minimum of technical expertise and no major equipment other than a scintillation counter.

Functional Effects of the Hypertrophic Cardiomyopathy R403Q Mutation Are Different in an α- or β-Myosin Heavy Chain Backbone

The R403Q mutation in the β-myosin heavy chain (MHC) was the first mutation to be linked to familial hypertrophic cardiomyopathy (FHC), a primary disease of heart muscle. The initial studies with R403Q myosin, isolated from biopsies of patients, showed a large decrease in myosin motor function, leading to the hypothesis that hypertrophy was a compensatory response. The introduction of the mouse model for FHC (the mouse expresses predominantly α-MHC as opposed to the β-isoform in larger mammals) created a new paradigm for FHC based on finding enhanced motor function for R403Q α-MHC. To help resolve these conflicting mechanisms, we used a transgenic mouse model in which the endogenous α-MHC was largely replaced with transgenically encoded β-MHC. A His6 tag was cloned at the N terminus of the α-and β-MHC to facilitate protein isolation by Ni2+-chelating chromatography. Characterization of the R403Q α-MHC by the in vitro motility assay showed a 30-40% increase in actin filament velocity compared with wild type, consistent with published studies. In contrast, the R403Q mutation in a β-MHC backbone showed no enhancement in velocity. Cleavage of the His-tagged myosin by chymotrypsin made it possible to isolate homogeneous myosin subfragment 1 (S1), uncontaminated by endogenous myosin. We find that the actin-activated MgATPase activity for R403Q α-S1 is ∼30% higher than for wild type, whereas the enzymatic activity for R403Q β-S1 is reduced by ∼10%. Thus, the functional consequences of the mutation are fundamentally changed depending upon the context of the cardiac MHC isoform.

Characterization of vascular smooth muscle cell phenotype in long-term culture

SummaryStudies of bovine carotid artery smooth muscle cells, during long-term in vitro subcultivation (up to 100 population doublings), have revealed phenotypic heterogeneity among cells, as characterized by differences in proliferative behavoir, cell morphology, and contractile-cytoskeletal protein profiles. In vivo, smooth muscle cells were spindle-shaped and expressed desmin and alpha-smooth muscle actin (50% of total actin) as their predominant cytoskeletal and contractile proteins. Within 24 h of culture, vimentin rather than desmin was the predominant intermediate filament protein, with little change in alpha-actin content. Upon initial subcultivation, all cells were flattened and fibroblastic in appearance with a concommitant fivefold reduction in alpha-actin content, whereas the beta and gamma nonmuscle actins predominated. In three out of four cell lines studied, fluctuations in proliferative activity were observed during the life span of the culture. These spontaneous fluctuations in proliferation were accompanied by coordinated changes in morphology and contractile-cytoskeletal protein profiles. During periods of enhanced proliferation a significant proportion of cells reverted to their original spindle-shaped morphology with a simultaneous increase in alpha-actin content (20 to 30% of total actin). These results suggest that in long-term culture smooth muscle cells undergo spontaneous modulations in cell phenotype and may serve as a useful model for studying the regulation of intracellular protein expression.

Myosin heavy chain isoform expression in rat smooth muscle development

Smooth muscle myosin heavy chains (MHCs), the motor proteins that power smooth muscle contraction, are produced by alternative splicing from a single gene. The smooth muscle MHC gene is capable of producing four isoforms by utilizing alternative splice sites located at the regions encoding the carboxy terminus and the junction of the 25- and 50-kDa tryptic peptides. These four isoforms, SM1A, SM1B, SM2A, and SM2B, are a combination of one of two heavy chains containing different carboxy-terminal tails (1 or 2) without (A) or with (B) an additional motif in the myosin head. In the present study, using RNA analysis and isoform-specific antibodies, we demonstrate the expression patterns of MHC isoforms during development in rat smooth muscle tissues. RNase protection analysis indicates that the mRNAs for SMA and SMB isoforms, which differ by a 21-nucleotide insertion in the region encoding the S1 head region of the myosin molecule, are differentially expressed during development in a highly tissue-specific manner. Smooth muscle MHC transcripts are first detectable in developing rat smooth muscle tissues at 17 days of fetal development. The SMB mRNA is shown to be expressed in smooth muscle from fetal bladder, intestine, and stomach and from neonatal aorta; however, it is not expressed in cultured smooth muscle cells from rat aorta. The SMA mRNA is also present at all stages of development in the smooth muscles examined; however, it is much less abundant than SMB mRNA in most fetal smooth muscles. We show here that the SMB isoform, which contains a unique seven-amino acid insertion at the junction of the 25- and 50-kDa tryptic peptides, is present in conjunction with SM1 and SM2 tails on immunoblots of smooth muscle from stomach, intestine, bladder, and uterus and is expressed during development in a pattern distinct from that of the SM1 and SM2 tail isoforms.Smooth muscle myosin heavy chains (MHCs), the motor proteins that power smooth muscle contraction, are produced by alternative splicing from a single gene. The smooth muscle MHC gene is capable of producing four isoforms by utilizing alternative splice sites located at the regions encoding the carboxy terminus and the junction of the 25- and 50-kDa tryptic peptides. These four isoforms, SM1A, SM1B, SM2A, and SM2B, are a combination of one of two heavy chains containing different carboxy-terminal tails (1 or 2) without (A) or with (B) an additional motif in the myosin head. In the present study, using RNA analysis and isoform-specific antibodies, we demonstrate the expression patterns of MHC isoforms during development in rat smooth muscle tissues. RNase protection analysis indicates that the mRNAs for SMA and SMB isoforms, which differ by a 21-nucleotide insertion in the region encoding the S1 head region of the myosin molecule, are differentially expressed during development in a highly tissue-specific manner. Smooth muscle MHC transcripts are first detectable in developing rat smooth muscle tissues at 17 days of fetal development. The SMB mRNA is shown to be expressed in smooth muscle from fetal bladder, intestine, and stomach and from neonatal aorta; however, it is not expressed in cultured smooth muscle cells from rat aorta. The SMA mRNA is also present at all stages of development in the smooth muscles examined; however, it is much less abundant than SMB mRNA in most fetal smooth muscles. We show here that the SMB isoform, which contains a unique seven-amino acid insertion at the junction of the 25- and 50-kDa tryptic peptides, is present in conjunction with SM1 and SM2 tails on immunoblots of smooth muscle from stomach, intestine, bladder, and uterus and is expressed during development in a pattern distinct from that of the SM1 and SM2 tail isoforms.

Lung smooth muscle differentiation

The vascular and visceral smooth muscle tissues of the lung perform a number of tasks that are critical to pulmonary function. Smooth muscle function often is compromised as a result of lung disease. Though a great deal is known about regulation of smooth muscle cell replication and cell and tissue contractility, much less is understood regarding the phenotype of the contractile protein machinery of lung smooth muscle cells. This review focuses on the expression of cytoskeletal and contractile proteins of lung vascular and airway smooth muscle cells during development, in the adult and during vascular and airway remodeling. Emphasis is placed on the expression of the heavy chain of smooth muscle myosin, as well as the regulation of its gene. Important areas for future research are discussed.

The relationship of mechanicalV max to myosin ATPase activity in rabbit and marmot ventricular muscle

Papillary muscle mechanics and ventricular myosin calcium-activated ATPase activity were measured in the same heart as a function of temperature (8–28°) in rabbits and marmots, in order to examine further the hypothesis that the velocity of cardiac muscle shortening at zero load (Vmax) is correlated with myosin ATPase activity. There was a similarQ10 forVmax in each muscle type, as measured with isotonic afterloaded quick-releases at 30–33% time-to-peak tension; the calcium activated ATPase of myosin in the two muscle types also was similar. The least squares linear regression of rabbitVmax on calcium-activated myosin ATPase activity was the same as in the marmot, so all the data were pooled to yield a linear regression (Y=0.47+3.82X) with a high correlation between the two variables [r=0.95,P<0.01 (ANOV)]. Furthermore, the correlation proved to be predictive of cardiacVmax and myosin ATPase activity levels in other experiments where these two measurements decreased below normal as a result of hypertrophic growth. Consequently, the quantitative relationship betweenVmax and myosin ATPase defined here may prove to be predictive of the ability of cardiac muscle to release bond energy.

Smooth muscle actin and myosin expression in cultured airway smooth muscle cells

In this study, the expression of smooth muscle actin and myosin was examined in cultures of rat tracheal smooth muscle cells. Protein and mRNA analyses demonstrated that these cells express alpha- and gamma-smooth muscle actin and smooth muscle myosin and nonmuscle myosin-B heavy chains. The expression of the smooth muscle specific actin and myosin isoforms was regulated in the same direction when growth conditions were changed. Thus, at confluency in 1 or 10% serum-containing medium as well as for low-density cells (50-60% confluent) deprived of serum, the expression of the smooth muscle forms of actin and myosin was relatively high. Conversely, in rapidly proliferating cultures at low density in 10% serum, smooth muscle contractile protein expression was low. The expression of nonmuscle myosin-B mRNA and protein was more stable and was upregulated only to a small degree in growing cells. Our results provide new insight into the molecular basis of differentiation and contractile function in airway smooth muscle cells.In this study, the expression of smooth muscle actin and myosin was examined in cultures of rat tracheal smooth muscle cells. Protein and mRNA analyses demonstrated that these cells express α- and γ-smooth muscle actin and smooth muscle myosin and nonmuscle myosin-B heavy chains. The expression of the smooth muscle specific actin and myosin isoforms was regulated in the same direction when growth conditions were changed. Thus, at confluency in 1 or 10% serum-containing medium as well as for low-density cells (50-60% confluent) deprived of serum, the expression of the smooth muscle forms of actin and myosin was relatively high. Conversely, in rapidly proliferating cultures at low density in 10% serum, smooth muscle contractile protein expression was low. The expression of nonmuscle myosin-B mRNA and protein was more stable and was upregulated only to a small degree in growing cells. Our results provide new insight into the molecular basis of differentiation and contractile function in airway smooth muscle cells.

Regulation of alpha-smooth muscle actin and CRBP-1 expression by retinoic acid and TGF-beta in cultured fibroblasts.

We have reported that Cellular Retinol Binding Protein‐1 (CRBP‐1) is expressed de novo during skin wound healing by a proportion of fibroblastic cells which then differentiate into myofibroblasts and express α‐smooth muscle actin. In fibroblasts cultured from different tissues we have shown that α‐smooth muscle actin expression, mainly controlled by Transforming Growth Factor‐β (TGF‐β), is also regulated by retinoic acid and that CRBP‐1, known to be a retinoic acid‐responsive gene, is modulated by TGF‐β. The aim of the present study has been to investigate the relationships between retinoic acid and TGF‐β in regulating the expression of CRBP‐1 and α‐smooth muscle actin in cultured rat subcutaneous tissue fibroblasts. We have observed that the TGF‐β‐induced, but not the retinoic acid‐induced, α‐smooth muscle actin expression is associated with a modulation of endogenous TGF‐β and TGF‐β receptors, suggesting that the action of retinoic acid on α‐smooth muscle actin expression is not mediated by TGF‐β. The expression of CRBP‐1 is regulated at the transcriptional level by TGF‐β and retinoic acid but not synergistically, suggesting a possible common pathway. However, retinoic acid, but not TGF‐β, increases the transcription of a transiently transfected chimeric construct containing the retinoic acid response element of the CRBP‐1 promoter, indicating that TGF‐β does not influence CRBP‐1 through the retinoic acid pathway. Our results indicate that distinct pathways regulate the genes involved in the appearance and evolution of the myofibroblastic cells. The characterization of these pathways will be helpful for the design of drugs influencing wound healing.

Microvessel precursor smooth muscle cells express head-inserted smooth muscle myosin heavy chain (SM-B) isoform in hyperoxic pulmonary hypertension.

Abstract The present study analyzes smooth muscle myosin heavy chain (SMMHC) expression as lung microvascular precursor smooth muscle cells (PSMCs), cells derived from fibroblasts and intermediate cells (immature SMCs), acquire a smooth muscle phenotype in anin vivo model of pulmonary hypertension (PH). Because of the unique contractile properties of the SMMHC isoform SM-B, we analyzed its expression in the microvessels (<100 μm diameter) and in larger vessels (100–700 μm) quantitatualy by the labeled [strept]avidin-biotin technique (day 1–28), and related this to cell phenotype by transmission microscopy and protein A-gold labeling (at day 28). Airway SMCs of the normal and hypertensive lung uniformly expressed SM-B whereas vascular SMC expression was heterogeneous. Thus, in some large arteries (and veins) SMCs contained cells expressing SM-B while in others all the cells were immunonegative. Microvascular cells expressing SM-B (arteries and veins) were rare in normal lung and numerous in PH, increasing as wall muscle developed in smaller segments with time. As in large vessels, some microvessels had immunopositive cells and others only negative ones. Ultrastructural analysis confirmed that the SMCs of bronchial vessels, and the septal SMCs adjoining alveolar ducts, contained dense filament arrays decorated with SM-B. While the PSMC processes of the normal lung contained sparse filaments decorated with SM-B, these cells expressed dense filament arrays in PH. Fibroblasts migrating to align around the microvessels also expressed SM-B but in the absence of a filament network. For the first time,we demonstrate in vivo that newly developed microvascular PSMCs express the SMMHC SM-B isoform in PH.