Theresa Hegmann scite author profile

Abstract.We have previously shown that chicken embryo fibroblast (CEF) cells and human bladder carcinoma (EJ) cells cbntain multiple isoforms of tropomyosin, identified as a, b, 1, 2, and 3 in CEF cells and 1, 2, 3, 4, and 5 in human EJ cells by one-dimensional SDS-PAGE (Lin, J. J.-C., D. M. Helfman, S. H. Hughes, and C.-S. Chou. 1985. J. Cell Biol. 100: 692-703; and Lin, J. J.-C., S. Yamashiro-Matsumura, and E Matsumura. 1984. Cancer Cells 1:57-65). Both isoform 3 (TM-3) of CEF and isoforms 4,5 (TM-4,-5) of human EJ cells are the minor isoforms found respectively in normal chicken and human cells. They have a lower apparent molecular mass and show a weaker affinity to actin filaments when compared to the higher molecular mass isoforms. Using individual tropomyosin isoforms immobilized on nitrocellulose papers and sequential absorption of polyclonal antiserum on these papers, we have prepared antibodies specific to CEF TM-3 and to CEF TM-1,-2. In addition, two of our antitropomyosin mAbs, CGI36 and CG3, have now been demonstrated by Western blots, immunoprecipitation, and two-dimensional gel analysis to have specificities to human EJ TM-3 and TM-5, respectively. By using these isoform-specific reagents, we are able to compare the intracellular localizations of the lower and higher molecular mass isoforms in both CEF and human EJ cells. We have found that both lower and higher molecular mass isoforms of tropomyosin are localized along stress fibers of cells, as one would expect. However, the lower molecular mass isoforms are also distributed in regions near ruffling membranes. Further evidence for this different localization of different tropomyosin isoforms comes from double-label immunofluorescence microscopy on the same CEF cells with affinity-purified antibody against TM-3, and monoclonal CGfl6 antibody against TM-a, -b, -1, and -2 of CEF tropomyosin. The presence of the lower molecular mass isoform of tropomyosin in ruffling membranes may indicate a novel way for the nonmuscle cell to control the stability and organization of microfilaments, and to regulate the cell motility.

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Scholarly Productivity and Occupational Stress Among Physician Assistant Educators

Hegmann

2020

J Physician Assist Educ

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Purpose Academic scholarship continues to challenge physician assistant (PA) educators in the United States, who typically enter academia with little experience in research or publication. Consequently, difficulty with navigating the promotion process might be expected to impact both job satisfaction and retention of PA faculty. Providing reasonable benchmarks for scholarship is one focus of this project, along with exploration of relationships among publication success, gender, job stressors, program support, and intent to leave academia. Methods Deidentified data from the online 2017 Faculty & Directors Survey was obtained from the Physician Assistant Education Association (PAEA), including gender, academic rank, program role, degree, publication numbers, and variables measuring program support, stressors, and intent to leave the institution or academia. Individual response rate was 60.3%, N = 1009. SPSS-v25 was used for data analysis. Results Respondents were 65% female. The mean number of total publications was 2.7 (down from 4.2 in 2010); the median was zero with 50.6% reporting no publications during their career. Almost half (45.5%) of PA faculty were stressed by research or publishing demands; 53.6% were stressed by the promotion process. Physician assistant educators stressed by promotion were more likely to consider leaving their institution or academia as a whole (Fisher's exact, P < .001 for both). Conclusion This study updates publication benchmarks for PA educators. Scholarship levels have dropped since 2010, likely related to the recent influx of junior faculty. Navigating the promotions process is a significant occupational stressor for PA educators and is associated with faculty intent to leave academia.

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Probing the role of nonmuscle tropomyosin isoforms in intracellular granule movement by microinjection of monoclonal antibodies.

Hegmann

Lin

1989

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Abstract. Chicken embryo fibroblast (CEF) cells were microinjected with several different monoclonal antibodies that recognize certain nonmuscle isoforms of tropomyosin. Immediately after injection, cells were recorded with a time-lapse video imaging system; later analysis of the tapes revealed that particles in cells injected with one of these antibodies (CG1, specific for CEF tropomyosin isoforms 1 and 3) showed a dramatic decrease in instantaneous speed while moving, distance moved per saltation, and proportion of time spent in motion. Injection of Fab fragments of CG1 resulted in similar changes in the pattern of granule movement. This inhibition of granule movement by CG1 antibody was reversible; at 2.5 h after injection, granules in injected cells had already reached threefourths of normal speed. The speed of granule movement in cells injected either with antibody specific for tropomyosin isoforms not present in CEF cells, or with CG1 antibody preabsorbed with tropomyosin, was not significantly different from the speed of granules in uninjected cells. When cells were injected with CG1 or Fab fragments of CG1, fixed, and counter-stained with rabbit antibodies to reveal the microtubule, microfilament, and intermediate filament systems, no obvious differences from the patterns normally seen in uninjected cells were observed. Examination of the ultrastrncture of injected cells by EM confirmed the presence of apparently intact and normal microtubule, actin, and intermediate filament networks.These experiments suggest that tropomyosin may play an important role in the movement of vesicles and organelles in the cell cytoplasm. Also, we have shown previously that the CG1 determinant can undergo a motility-dependent change in reactivity, that may be important for the regulatory function of nonmuscle tropomyosin (Hegmann, T. E., J. L.-C. Lin, and J. J.-C. Lin. 1988. J. Cell Biol. 106:385-393). Therefore, in addition to postulated microtubule-based motors, microfilaments may play a critical role in regulating granule movement in nonmuscle cells.

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Physician Assistant Program Director Opinions Regarding the Importance of Faculty Research and Publication

Hegmann

Dehn

2006

The Journal of Physician Assistant Education

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Inhibition of intracellular granule movement by microinjection of monoclonal antibodies against caldesmon

Hegmann

Schulte

Lin

et al. 1991

Cell Motil. Cytoskeleton

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Monoclonal antibodies, C2, C9, C18, and C21, against chicken gizzard caldesmon (called high molecular weight isoform) were shown to crossreact with a low molecular weight isoform of caldesmon in chicken embryo fibroblasts (CEF). These antibodies were used in a microinjection study to investigate the in vivo function of caldesmon in nonmuscle cell motility. Injected cells did not appear to change their morphology significantly; the cells displayed a flat appearance and were able to ruffle and locomote normally. However, in the C21 injected cells, saltatory movements of granules and organelles appeared to be greatly inhibited. This inhibition of granule movement was reversible, so that by 3 hr after injection, granules in injected cells had already recovered to normal speed. The inhibition of granule movement in cells injected with C2, C9, or C18 antibody, or with C21 antibody preabsorbed with caldesmon, were not significantly different from that in uninjected cells. In a previous epitope study, we demonstrated that, of the antibodies used in this study, only C21 antibody was able to compete with the binding of caldesmon to Ca++/calmodulin and to F-actin, although both C21 and C2 antibodies recognized the same carboxyl-terminal 10K fragment of gizzard caldesmon [Lin et al., 1991: Cell Motil. Cytoskeleton 20:95-108]. The caldesmon distribution in C21 injected cells changed from stress-fiber localization to a more diffuse appearance, when the injection was performed at 10-30 mg/ml of C21 antibody. We have previously shown that a monoclonal anti-tropomyosin antibody exhibited motility-dependent recognition of an epitope, and that microinjection of this antibody specifically inhibited intracellular granule movements of CEF cells [Hegmann et al., 1989: J. Cell Biol. 109:1141-1152]. Therefore, it is likely that tropomyosin and caldesmon may both function in intracellular granule movement by regulating the contractile system in response to [Ca++] change inside nonmuscle cells.

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Theresa Hegmann

Differential localization of tropomyosin isoforms in cultured nonmuscle cells.

Scholarly Productivity and Occupational Stress Among Physician Assistant Educators

Probing the role of nonmuscle tropomyosin isoforms in intracellular granule movement by microinjection of monoclonal antibodies.

Physician Assistant Program Director Opinions Regarding the Importance of Faculty Research and Publication

Inhibition of intracellular granule movement by microinjection of monoclonal antibodies against caldesmon

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