DNA synthesis in cultures of atrial and ventricular cardiomyocytes in the rat

By means of 3H-thymidine autoradiography DNA replicative activity has been studied in cultured atrial and ventricular myocytes, and non-muscle cells from hearts of 2-week-old rats (age when cell proliferation in the myocardium is already significantly depressed). PAS-reaction was used as a cytochemical marker of cardiomyocytes: atrial myocytes are richer in glycogen than ventricular cells. Labeling indices of atrial myocytes after a 24 hour exposure to 3H-thymidine were higher than ventricular ones: on day 6 of culturing--47 and 5%, and on day 11-34 and 8%, respectively. After 10 days of culturing the number of binucleated atrial myocytes, non-typical for atrial myocardium in vivo, increased by 25-40% as compared with 8-13% on days 2-3 in culture. In 10-day cultures, 3- and 4-nucleated atrial myocytes were observed. Both mononucleated and binucleated atrial and ventricular myocytes incorporated 3H-thymidine. To find out whether the deeper inhibition of replicative activity in ventricular myocytes influences fibroblasts and endothelial cells from ventricles, the proliferative activity of non-muscle cells was studied. Non-muscle cells, both in atrial and ventricular cultures, behaved as a totally proliferating population (labeling indices on the 6th day are about 75-90%) and their growth rate decreased during the formation of the contact-inhibited monolayer. These cells, contrary to myocytes, are predominantly mononucleated in all the periods studied. The deeper depression of replication in ventricular myocytes appears to be related with their higher level of differentiation as compared to myocytes of the atrial myocardium.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effect of systemic inhibition of prostaglandin synthesis on muscle protein balance after trauma in the rat

Anaesthetized rats were subjected to a single impact trauma to the medial aspect of the right hindlimb (gastrocnemius muscle), and were compared with sham-treated controls. For 3 days after injury, muscles of the traumatized limb showed a marked catabolic response. Muscle protein repletion commenced after day 3, however, this process was not complete until 21 days after injury. Muscles of the uninjured limb of the traumatized rats also showed a distinct catabolic response, compared with rats that were never injured, although this response was less in magnitude than that of the injured limb. At 3 days after trauma, augmented synthesis of prostaglandin (PG)E2 by muscles of the injured and uninjured limb provided evidence of a local and systemic inflammatory response. Inhibition of PG synthesis by the systemic administration of naproxen (6-methoxy-alpha-methyl-2-napthaleneacetic acid) significantly reduced the catabolic loss of muscle protein seen locally and peripherally to the injury site.     

The myocardial response to adrenomedullin involves increased cAMP generation as well as augmented Akt phosphorylation

In this work we aimed to observe (1) the changes in adrenomedullin (AM) and its receptor system - calcitonin receptor-like receptor (CRLR) and receptor activity modifying proteins (RAMPs) - in myocardial ischemic injury and (2) the response of injuried myocardia to AM and the phosphorylation of Akt to illustrate the protective mechanism of AM in ischemic myocardia. Male SD rats were subcutaneously injected with isoproterenol (ISO) to induce myocardial ischemia. The mRNA levels of AM, CRLR, RAMP1, RAMP2 and RAMP3 were determined by RT-PCR. Protein levels of Akt, phosphor-Akt, CRLR, RAMP1, RAMP2 and RAMP3 were assayed by Western blot. Results showed that, compared with that of the controls, ISO-treated rats showed lower cardiac function and myocardial injury. The mRNA relative amount of AM, CRLR, RAMP1, RAMP2 and RAMP3 in the myocardia of ISO-treated rats was increased. The elevated mRNA levels of CRLR, RAMP1, RAMP2 and RAMP3 were positively correlated with AM content in injured myocardia. The protein levels of CRLR, RAMP1, RAMP2 and RAMP3 in injured myocardia were increased compared with that of control myocardia. AM-stimulated cAMP generation in myocardia was elevated in the ISO group, and was antagonized by AM(22-52) and CGRP(8-37). Western blot analyses revealed that AM significantly enhanced Akt phosphorylation in injured myocardia, which was blocked by pretreatment with AM(22-52) or CGRP(8-37). Ischemia-injured myocardia hyper-expressed AM and its receptors - CRLR, RAMP1, RAMP2 and RAMP3 - and the response of ischemic myocardia to AM was potentiated, and the level of Akt phosphorylation was also increased, which suggests that changes in cardiac AM/AM receptor might play an important role in the pathogenesis of myocardial ischemic injury.     

The response of the atrium to direct mechanical wounding in the adult heart of the newt,Notophthalmus viridescens

Summary Wound repair and proliferation were examined in the injured newt atrium with light- and electron-microscopic techniques including autoradiography. Hearts were injured by removing a piece approximately 0.5 mm² of the atrial wall. The five-day wound was an endothelial and mesothelial-lined blood clot bordered by a 150-m necrotic zone. Repair progressed from the periphery inward with areas of macrophage activity replaced by fibroblasts and connective tissue. The wound at 25 days consisted of a scar with few myocytes. There was no difference in the proliferative behavior between the right and left atria. Proliferative cells were localized to a 500-m reactive zone surrounding the wound. The maximum mesothelial cell thymidine-labeling index of 20.5% and mitotic index of 1.4% were seen 5 days after injury. The peak connective tissue cell thymidine-labeling index of 10.2% and mitotic index of 0.4% were seen 10 days after wounding. The peak thymidine-labeling index of 9.8% for myocardial cells was recorded 10 days after injury with a mitotic index of 0.2%. Proliferation returned to control levels by 25 days post-injury. Electron microscopy demonstrated that myocytes engaged in DNA synthesis were indistinguishable from control myocytes. Z-band material was not observed in mitotic myocytes, but myofilaments and junctions were present.     

Expression of T-cadherin in the rat carotid artery wall after balloon injury and in different rat organs

T-cadherin is an unusual glycosilphosphatidylinositol (GPI)-anchored member of the cadherin family of cell adhesion proteins. In contrast to classical cadherins, tissue distribution of T-cadherin so far remained unknown. We examined tissue distribution of T-cadherin in rats using Western blotting and immunohistochemical method. Our results show that T-cadherin is expressed in all types of muscles (cardiac, striated, and smooth muscles), in brain neurons, and spinal cord, in the vessel endothelium, at the apical pole of intestinal villar epithelium, in the basal layer of skin, and eosophagal epithelium. Blood-derived and lymphoid cells as well as connective tissue were T-cadherin-negative. The highest level of T-cadherin expression was revealed in the cardiovascular system. Although T-cadherin was detected in smooth muscle cells, its role in the intimal thickening and restenosis is not known. We examined T-cadherin expression within 1-28 days after balloon injury of rat left carotid arteries. T-cadherin expression was valued immunohistochemically with semiquantitative method. In uninjured arteries, T-cadherin was expressed in endothelial (vWF-positive) cells, and smooth muscle (alpha-actin-positive) cells (SMCs). After denudation of arterial wall, T-cadherin was present both in the media and neointima. We revealed dynamics of T-cadherin expression in the media of injured artery: an essential increase being registered at the stage of cell migration and proliferation in the media and neointima (1-7 days), followed by its decrease to the baseline level (10-28 days). The high upregulation of T-cadherin expression in the media and neointima during migration and proliferation of vascular cells after vessel injury enables us to suggest the involvement of T-cadherin in vessel remodeling after balloon catheter injury.     

Proliferative processes in the myocardium in different parts of the heart during the creation of experimental myocardial infarct of the left ventricle in 2- and 3-week-old rats

As a result of 30 times repeated injections of 3H-thymidine (3HTdr) to neonate rats, beginning from days 13 or 21 post partum, ca. 20 and 10% of myonuclei in the left and right atria were labeled, respectively, while in both ventricles cumulative labeling of myocytes was nearly ten times lower. In rats of the same age with experimental infarction of the left ventricular myocardium the number of myonuclei labeled after 30-fold 3HTdr injections increased in atria up to 40-50%, in perinecrotic myofibers of the left ventricles up to 8-11%, and in myofibers of the left and right ventricle located far from the necrotic foci up to 3-4 and 2-3%, respectively. In some of rats subendocardial and/or subepicardial layers of the surviving left ventricular myocardium contained up to 15-35% of labeled myonuclei. Thus, in neonatal rats the extent of DNA synthesis reactivation in the nuclei of cardiomyocytes, the majority of which have recently completed normal ontogenetic proliferation, is, on the whole, of the same order as found in similar experiments on adult rats (Rumiantsev, Kassem, 1976; Oberpriller et al., 1984). However, still immature ventricular myocytes of neonatal rats resume mitotic cycle easier than those of adult animals which is evidenced not only by higher numbers of 3HTdr labeled myonuclei in subepicardial and subendocardial ventricular myocardia of some rats, but even more by reactivation of DNA synthesis in a limited fraction (2-3%) of the whole population of non-perinecrotic myocytes in both ventricles. Besides, reactive proliferation of cardiomyocytes in the atria of neonate rats, unlike in adults, starts on day 3 rather than on day 5 after infarction is induced. In the atria of neonatal rats polyploidization of myonuclei at later postinfarction stages is less pronounced than in adult rats which may be accounted for by formation of individual daughter nuclei during acytokinetic mitoses or, more seldom, by completion of cytotomy.     

Effect of helium-neon laser rays on the processes of postradiation recovery in the skeletal muscles of old rats

The present experiments were conducted to determine the stimulant effect of helium-neon laser on the postradiation recovery in irradiated uninjured skeletal muscle of rats aged 2-2.5. This was indicated by a restored ability of the muscle for posttraumatic regeneration. The both hind rat legs were exposed to local irradiation of 20 Gy and following laser therapy (8-9 procedures at 3 min each, impulsive or continuous one). Then both musculus gastrocnemius were cut across 30 days after irradiation. It was shown that laser therapy employed before injury of the irradiated muscle accelerated fibrin resorption and improved connective tissue, but slightly stimulated muscular tissue. Impulse laser therapy was more favourable for state of skin and healing of the skin wound after irradiation.     

Regional appearance of atrial natriuretic peptide in the ventricles of infarcted rat hearts

The appearance of atrial natriuretic peptide (ANP) in the ventricular myocardium was investigated in rat hearts subjected to severe left ventricular infarction. The left coronary artery was ligated for 1, 2, 3, 4 and 6 days and for 3 weeks, and the tissue was prepared for microscopic examination of immunoreactive ANP and for electron microscopy. In the normal and sham-operated hearts, and in hearts subjected to 1 day of coronary ligation, ANP immunoreactivity was restricted to a few ventricular myocytes of the conduction system. Following 2–3 days of coronary ligation, ANP immunoreactivity was detected in the viable myocardium of the lateral border of the infarct and in a few layers of viable cardiac myocytes located in the subendocardial areas of the ischemic left free ventricular wall. Further, during the following days and after 3 weeks of coronary ligation, a gradient of specific labeling was commonly seen across the lateral border area of the infarct. Thus, the strongest immunoreactivities were present in the cardiac myocytes located adjacent to the non-contracting myocardium. Electron microscopic examination of the immunoreactive cardiac myocytes confirmed the presence of electron-dense specific granules within these cells. The present findings suggest that the increased regional production of ANP within the ventricular myocardium is induced by increased mechanical stretch of the cardiac myocytes, and that this might contribute to the increased release of ANP in myocardial infarction.     

THYROID PROLIFERATIVE POTENTIAL AS A FUNCTION OF AGE

The effect of a goitrogenic stimulus on thyroid weight and thyroid cell ³HTdR labeling of Sprague-Dawley rats varying from 2 to 40 weeks of age was determined. Propylthiouracil ad libitum in drinking water produced a spurt in follicle cell labeling index and thyroid weight evident after 24 hr for all age groups. The increase in labeling index reached a peak at 5–7 days and then decreased to a level a few times greater than that of the normal unstimulated thyroid. The tritiated thymidine labeling index for thyroid follicle cells and the effect of PTU thereon was determined for August male rats of 3 days to 12 weeks of age. In the older rats, the follicle cell labeling index rose to 5–6% after 4–5 days of PTU treatment and then slowly fell to about 1%, For the unstimulated control rat of comparable age, the labeling index was about 0.1%. At all ages the thyroid showed a rapid response to PTU. Examination of the time sequence of mitotic labeling showed that the DNA synthesis period was 7.5 hr for normal 2-week-old rats and for 10–12-week-old rats that had received PTU for 4 days. There was no second wave of labeled mitoses in either group during the 48-hr interval studied. From the curve of thyroid weight vs time on PTU and from the labeled mitoses curve, inferences regarding the minimum fraction of proliferating follicle cells in the stimulated ‘adult’rat thyroid were made.     

Neutrophil-mediated accumulation of 2-ClHDA during myocardial infarction: 2-ClHDA-mediated myocardial injury

The pathophysiological sequelae of myocardial infarction include neutrophil infiltration into the infarct zone that contributes to additional damage to viable tissue and removal of cellular debris from necrosed tissue. Reactive chlorinating species produced by myeloperoxidase amplify the oxidant capacity of activated neutrophils. Plasmalogens are a major phospholipid subclass of both endothelial cells and cardiac myocytes. Recent studies have shown that plasmalogens are targeted by neutrophil-derived reactive chlorinating species that lead to the production of alpha-chloro fatty aldehydes. Results herein demonstrate that the alpha-chloro fatty aldehyde 2-chlorohexadecanal (2-ClHDA) accumulates in rat hearts subjected to left anterior descending coronary artery occlusion. Myocardia from rats subjected to surgical infarction had increased 2-ClHDA and neutrophil infiltration levels compared with myocardia from rats subjected to sham surgery. Additionally, infarcted myocardia from rats rendered neutropenic by treatments with an anti-neutrophil antibody had diminished 2-ClHDA and neutrophil infiltration levels compared with infarcted myocardia from normopenic rats; 2-ClHDA was shown to elicit myocardial damage as determined by lactate dehydrogenase release in isolated perfused rat hearts. Additionally, 2-ClHDA treatment of hearts resulted in decreased heart rate and ventricular performance. Taken together, the present results demonstrate a novel neutrophil-dependent myeloperoxidase-based mechanism that results in 2-ClHDA production in response to regional myocardial infarction that may also contribute to cardiac dysfunction.     

Expression of bone morphogenic proteins and receptors at the injured growth plate cartilage in young rats.

The injured growth plate cartilage is often repaired by bony tissue, resulting in impaired bone growth in children. Bone morphogenic proteins (BMPs) are important for bone fracture repair, and as a step to characterize potential involvement of BMPs in bony repair of injured growth plate, expression of BMPs and receptors (BMP-R) was examined by quantitative RT-PCR and immunohistochemistry in rat injured tibial growth plate. During the inflammatory response on day 1, slightly increased expression of BMP-3, BMP-4, BMP-R1a, and BMP-R2 was observed, with immunostaining seen among inflammatory cells at the injury site. During mesenchymal infiltration and osteogenic responses on days 3-14, moderately increased expression of BMP-2, -3, -4, -7, and BMP-R1a was found, with immunostaining observed among infiltrated mesenchymal cells and differentiated osteoblasts lining bony trabeculae. During maturation phase on days 14-25, only BMP-7 was seen upregulated slightly and was localized in osteoblasts and marrow cells at the injury site. The temporospatial expression of BMPs and receptors at the injured growth plate suggests potential involvement of BMP-3 and -4 in regulating the inflammatory response or as its mediators in modulating downstream events, and BMP-2, -3, -4, and -7 in the fibrogenic and osteogenic responses, and BMP-7 in bone remodeling at the injured growth plate.     

Qualitative and quantitative study of wound healing processes in the coelenterate, Plexaurella fusifera: spatial, temporal, and environmental (light attenuation) influences

Following injury, the Caribbean soft coral, Plexaurella fusifera, forms an epithelial front containing amoebocytes and zooxanthellae, a photosynthetic endosymbiont. Amoebocytes may be responsible for extruding the connective mesogleal fibers necessary for regeneration of tissue and zooxanthellae may provide the energy for repair. This study examined the effects of time, space, and environment (light attenuation) on wound healing in this coral species and quantitatively confirmed the increase of amoebocyte concentrations in the injured area. A wound was made on coral branchlets by removing approximately 4.5 mm of coenenchyme. At assigned times after injury, samples were collected for gross morphological and histological evaluation, in which amoebocytes and zooxanthellae concentrations were quantified within 0.009 mm3 of tissue. Overall amoebocyte numbers within uninjured and wounded tissue were similar. However, when numbers of amoebocytes per area of injured tissue were calculated and compared to those of uninjured tissue, 82.4% more amoebocytes occurred at distances 0-0.5 mm from the wound edge, while areas of tissue >2 mm from the wound edge were occupied by fewer amoebocytes. Overall increases in concentrations of zooxanthellae also occurred within wounded coral, but no apparent temporal, spatial, or light-related pattern was detected. Therefore, this study supports the conjecture that amoebocyte accumulation at a wound site is an effect of cells migrating from uninjured tissue adjacent to the wounded edge. In addition, this movement occurs regardless of light attenuation. Light, which in this study was confined to ranges between 70 and 545 microE s-1 m-2, did not significantly affect the wound healing process in regard to either closure or cellular concentrations.     

Hindlimb suspension reduces muscle regeneration

Exposure of juvenile skeletal muscle to a weightless environment reduces growth and satellite cell mitotic activity. However, the effect of a weightless environment on the satellite cell population during muscle repair remains unknown. Muscle injury was induced in rat soleus muscles using the myotoxic snake venom, notexin. Rats were placed into hindlimb-suspended or weightbearing groups for 10 days following injury. Cellular proliferation during regeneration was evaluated using 5-bromo-2′-deoxyuridine (BrdU) immunohistochemistry and image analysis. Hindlimb suspension reduced (P<0.05) regenerated muscle mass, regenerated myofiber diameter, uninjured muscle mass, and uninjured myofiber diameter compared to weightbearing rats. Hindlimb suspension reduced (P<0.05) BrdU labeling in uninjured soleus muscles compared to weightbearing muscles. However, hindlimb suspension did not abolish muscle regeneration because myofibers formed in the injured soleus muscles of hindlimb-suspended rats, and BrdU labeling was equivalent (P>0.10) on myofiber segments isolated from the soleus muscles of hindlimb-suspended and weightbearing rats following injury. Thus, hindlimb suspension (weightlessness) does not suppress satellite cell mitotic activity in regenerating muscles before myofiber formation, but reduces growth of the newly formed myofibers. Accepted: 11 December 1997     

The capacity for reactive DNA synthesis of the myocytes in the heart conduction system in experimental and clinical myocardial pathology]

The DNA synthesis has been studied in the conductive system (CS) myocytes, compared to that in atrial and ventricular myocytes: 1) in the left ventricular myocardial infarction induced in two- and three-week-old and adult rats, 2) after isoproterenol injections to adult rats and mice, and 3) in the hypertrophied human heart. The extent of DNA synthesis reactivation was evaluated by the cumulative labeling indices in experiments with multiple 3HTdR injections to rats and mice. In the human cardiac myocyte nuclei, the DNA content was determined by the Feulgen-cytophotometry. The difference between the control and experimental mean values of the labeling indices for CS myocyte nuclei was statistically significant only for atrioventricular part of the CS in the infarcted hearts of adult rats. In the human heart CS the ability of myocytes to polyploidization varies from one cell type to another, the lowest being in nodal cells.     

Analysis of population cytokinetics of chick myocardial cells in tissue culture

The growth of embryonic chick cardiac myocytes and fibroblasts in tissue culture was evaluated by the kinetics of nuclear labeling during continuous exposure to [3H]thymidine. The fraction of mitotically active cells, the mean intermitotic period and the population doubling times were determined in each cell type during 3 weeks in culture. After 24 hr in culture, 90% of the muscle cells were mitotically active with minimal population doubling times of 65 hr. By 17 days in culture only 5% of the myocytes continued to divide with population doubling times greater than 3000 hr. Primarily, the lengthening of doubling times was due to a withdrawal of cells from the mitotic cycle and much less to a lengthening of the intermitotic period. Growth of cardiac muscle cells from embryonic hearts from 4 to 10 days of development was also compared. Muscle cells from younger hearts displayed greater mitotic activity than those from older hearts at equivalent times in culture.     

Macrophages are comprised of resident brain microglia not infiltrating peripheral monocytes acutely after neonatal stroke

Macrophages can be both beneficial and detrimental after CNS injury. We previously showed rapid accumulation of macrophages in injured immature brain acutely after ischemia-reperfusion. To determine whether these macrophages are microglia or invading monocytes, we subjected post-natal day 7 (P7) rats to transient 3 h middle cerebral artery (MCA) occlusion and used flow cytometry at 24 and 48 h post-reperfusion to distinguish invading monocytes (CD45high/CD11b+) from microglia (CD45low/medium/CD11b+). Inflammatory cytokines and chemokines were determined in plasma, injured and contralateral tissue 1-24 h post-reperfusion using ELISA-based cytokine multiplex assays. At 24 h, the number of CD45+/CD11b+ cells increased 3-fold in injured compared to uninjured brain tissue and CD45 expression shifted from low to medium with less than 10% of the population expressing CD45high. MCA occlusion induced rapid and transient asynchronous increases in the pro-inflammatory cytokine IL-beta and chemokines cytokine-induced neutrophil chemoattractant protein 1 (CINC-1) and monocyte-chemoattractant protein 1 (MCP-1), first in systemic circulation and then in injured brain. Double immunofluorescence with cell-type specific markers showed that multiple cell types in the injured brain produce MCP-1. Our findings show that despite profound increases in MCP-1 in injured regions, monocyte infiltration is low and the majority of macrophages in acutely injured regions are microglia.     

Transient decreases in forelimb gait and ground reaction forces following rotator cuff injury and repair in a rat model

Due to inadequate healing, surgical repairs of torn rotator cuff tendons often fail, limiting the recovery of upper extremity function. The rat is frequently used to study rotator cuff healing; however, there are few systems capable of quantifying forelimb function necessary to interpret the clinical significance of tissue level healing. We constructed a device to capture images, ground reaction forces and torques, as animals ambulated in a confined walkway, and used it to evaluate forelimb function in uninjured control and surgically injured/repaired animals. Ambulatory data were recorded before (D–1), and 3, 7, 14, 28 and 56 days after surgery. Speed as well as step width and length were determined by analyzing ventral images, and ground reaction forces were normalized to body weight. Speed averaged 22±6 cm/s and was not affected by repair or time. Step width and length of uninjured animals compared well to values measured with our previous system. Forelimbs were used primarily for braking (?1.6±1.5% vs +2.5±0.6%), bore less weight than hind limbs (49±5% vs 58±4%), and showed no differences between sides (49±5% vs 46±5%) for uninjured control animals. Step length and ground reaction forces of the repaired animals were significantly less than control initially (days 3, 7 and 14 post-surgery), but not by day 28. Our new device provided uninjured ambulatory data consistent with our previous system and available literature, and measured reductions in forelimb function consistent with the deficit expected by our surgical model.     

Increased protein O-GlcNAc modification inhibits inflammatory and neointimal responses to acute endoluminal arterial injury

Inflammation plays a major role in vascular disease. We have shown that leukocyte infiltration and inflammatory mediator expression contribute to vascular remodeling after endoluminal injury. This study tested whether increasing protein O-linked-N-acetylglucosamine (O-GlcNAc) levels with glucosamine (GlcN) and O-(2-acetamido-2-deoxy-d-glucopyranosylidene) amino-N-phenylcarbamate (PUGNAc) inhibits acute inflammatory and neointimal responses to endoluminal arterial injury. Ovariectomized rats were treated with a single injection of GlcN (0.3 mg/g ip), PUGNAc (7 nmol/g ip) or vehicle (V) 2 h before balloon injury of the right carotid artery. O-GlcNAc-modified protein levels decreased markedly in injured arteries of V-treated rats at 30 min, 2 h, and 24 h after injury but returned to control (contralateral uninjured) levels after 14 days. Both GlcN and PUGNAc increased O-GlcNAc-modified protein levels in injured arteries compared with V controls at 30 min postinjury; the GlcN-mediated increase persisted at 24 h but was not evident at 14 days. Proinflammatory mediator expression increased markedly after injury and was reduced significantly (30-50%) by GlcN and PUGNAc. GlcN and PUGNAc also inhibited infiltration of neutrophils and monocytes in injured arteries. Chronic (14 days) treatment with GlcN reduced neointima formation in injured arteries by 50% compared with V controls. Acute GlcN and PUGNAc treatment increases O-GlcNAc-modified protein levels and inhibits acute inflammatory responses in balloon-injured rat carotid arteries; 14 day GlcN treatment inhibits neointima formation in these vessels. Augmenting O-GlcNAc modification of proteins in the vasculature may represent a novel anti-inflammatory and vasoprotective mechanism.     

Platelet Recruitment Promotes Keratocyte Repopulation following Corneal Epithelial Abrasion in the Mouse

Corneal abrasion not only damages the epithelium but also induces stromal keratocyte death at the site of injury. While a coordinated cascade of inflammatory cell recruitment facilitates epithelial restoration, it is unclear if this cascade is necessary for keratocyte recovery. Since platelet and neutrophil (PMN) recruitment after corneal abrasion is beneficial to epithelial wound healing, we wanted to determine if these cells play a role in regulating keratocyte repopulation after epithelial abrasion. A 2 mm diameter central epithelial region was removed from the corneas of C57BL/6 wildtype (WT), P-selectin deficient (P-sel^-/-), and CD18 hypomorphic (CD18^hypo) mice using the Algerbrush II. Corneas were studied at 6h intervals out to 48h post-injury to evaluate platelet and PMN cell numbers; additional corneas were studied at 1, 4, 14, and 28 days post injury to evaluate keratocyte numbers. In WT mice, epithelial abrasion induced a loss of anterior central keratocytes and keratocyte recovery was rapid and incomplete, reaching ~70% of uninjured baseline values by 4 days post-injury but no further improvement at 28 days post-injury. Consistent with a beneficial role for platelets and PMNs in wound healing, keratocyte recovery was significantly depressed at 4 days post-injury (~30% of uninjured baseline) in P-sel^-/- mice, which are known to have impaired platelet and PMN recruitment after corneal abrasion. Passive transfer of platelets from WT, but not P-sel^-/-, into P-sel^-/- mice prior to injury restored anterior central keratocyte numbers at 4 days post-injury to P-sel^-/- uninjured baseline levels. While PMN infiltration in injured CD18^hypo mice was similar to injured WT mice, platelet recruitment was markedly decreased and anterior central keratocyte recovery was significantly reduced (~50% of baseline) at 4–28 days post-injury. Collectively, the data suggest platelets and platelet P-selectin are critical for efficient keratocyte recovery after corneal epithelial abrasion.     

Mitotic activity, ploidy and ultrastructure of cardiomyocytes from human embryo and fetuses

There is an evidence that mitotic activity of human cardiomyocytes in late fetal and early postnatal ontogenesis is very low. But little is known of the division of human cardiomyocytes at earlier stages of development. In this study mitotic activity of ventricular and atrial human cardiomyocytes of 4-8-week-old embryos and 17-32-week-old fetuses has been studied. On these stages the mitotic index is relatively low to reduce moderately within the 1st to the 3rd trimester of pregnancy from 1.4 to 0.7%. These findings are consistent with the data on cell ploidy demonstrating the presence of relatively small share of myocytes with 3c and 4c DNA in ventricles of 6-8-week-old embryos and 12-22-week-old fetuses. The share of such cells in the 1st and 2nd trimesters of pregnancy varies from 19 to 24% and from 8 to 18%, respectively. Cells with 3c and 4c DNA are most likely to be in mitotic cycle. This assumption is supported by electron microscope pictures showing all phases of typical mitosis. Cyclic changes of myofibrillar ultrastructure during mitosis of prenatal human cardiomyocytes are the same as during mitosis of low differentiated myocytes in mouse and rat hearts. These results suggest that in prenatal human cardiomyogenesis the level of myocyte differentiation and the cell number increase at slow rate.