Alexander Sandra

Fetal hemorrhage and platelet dysfunction in SLP-76-deficient mice.

The adapter protein SLP-76 is expressed in T lymphocytes and hematopoietic cells of the myeloid lineage, and is known to be a substrate of the protein tyrosine kinases that are activated after ligation of the T-cell antigen receptor. Transient overexpression of SLP-76 in a T-cell line potentiates transcriptional activation after T-cell receptor ligation, while loss of SLP-76 expression abrogates several T-cell receptor-dependent signaling pathways. Mutant mice that lack SLP-76 manifest a severe block at an early stage of thymocyte development, implicating SLP-76 in signaling events that promote thymocyte maturation. While it is clear that SLP-76 plays a key role in development and activation of T lymphocytes, relatively little is understood regarding its role in transducing signals initiated after receptor ligation in other hematopoietic cell types. In this report, we describe fetal hemorrhage and perinatal mortality in SLP-76-deficient mice. Although megakaryocyte and platelet development proceeds normally in the absence of SLP-76, collagen-induced platelet aggregation and granule release is markedly impaired. Furthermore, treatment of SLP-76-deficient platelets with collagen fails to elicit tyrosine phosphorylation of phospholipase C-gamma2 (PLC-gamma2), suggesting that SLP-76 functions upstream of PLC-gamma2 activation. These data provide one potential mechanism for the fetal hemorrhage observed in SLP-76-deficient mice and reveal that SLP-76 expression is required for optimal receptor-mediated signal transduction in platelets as well as T lymphocytes.

Insulin, insulin-like growth factors, and vascular endothelium

Endothelial cells form the intimal lining of the entire vascular system. The vascular endothelium is continuously and directly bathed by components of the bloodstream and represents the initial fixed anatomical surface with which these components come in contact. In the past decade, the methodologies for studying endothelial cell functions have markedly advanced, enabling direct and detailed study of the vascular endothelium. From such studies, it is now apparent that the vascular endothelium represents an extraordinarily complex network of cells demonstrating a multitude of distinct anatomic, metabolic, and immunologic properties critical to such processes as angiogenesis, atherosclerosis, thrombosis, neoplasia, and a variety of metabolic disorders including homocystinuria and diabetes mellitus. This report will focus on the interactions of insulin and the insulin-like growth factors (IGFs) with vascular endothelium, based on studies with cultured endothelial cells, isolated microvessels, and perfused organ systems. Data will be presented relevant to the following concepts: (1) endothelial cells, in culture and in vivo, have specific receptors for insulin, IGF-I, and IGF-II; (2) insulin, IGF-I, and IGF-II have both distinct and overlapping functions in cultured endothelial cells; (3) cultured endothelial cells process receptor-bound insulin, IGF-I, and IGF-II, by distinct processes; (4) in vivo, capillary endothelial receptors are integrally involved in the transport of intact insulin to subendothelial sites of insulin action; and (5) vascular endothelium has specialized cellular features that are likely to contribute to the unique interactions of endothelial cells with insulin and the IGFs.

Vascular endothelial growth factor expression coincides with coronary vasculogenesis and angiogenesis.

Vascular endothelial growth factor (VEGF) plays an important role in early embryonic vasculogenesis. To establish its temporal expression and localization in the heart during development, we studied rat hearts from the first embryonic day (E) of myocardial vascular tube formation through the early postnatal period. Ventricular VEGF immunoreactivity was noted in the epicardium and the thin underlying myocardium in E10 ventricles. During the earliest stages of vascularization (E13–E16) immunoreactivity was highest in the compact myocardium nearest the epicardium, and subsequently (E18 and thereafter) became more evenly distributed transmurally. By birth (E22) immunoreactivity was most intense around microvessels. Similarly, VEGF mRNA localization, demonstrated by in situ hybridization, was initially highest near the epicardium and then became more evenly distributed transmurally by late gestation. Within the interventricular septum, the highest expression occurred in the middle of the wall where it correlated with the greatest vascularization. Northern blot analysis showed that from E12 through the first 10 days of postnatal life, VEGF was two to three times higher than in the adult. Western blot analysis showed that VEGF tended to be higher in the atria than the ventricles, and negligible in the outflow tract. Our data indicate that VEGF localization and expression 1) correspond to the pattern of vascularization in the embryonic/fetal heart, and 2) remain high during the early postnatal period when capillary proliferation is high. Because VEGF is stimulated by hypoxia, its preferential mRNA expression near the epicardium, that is, farthest from the ventricular lumen and the O2 source, fits with the hypothesis that a hypoxic gradient is a driving force in the transmural vascularization process. Dev Dyn 1999;215:54–61.

Role of VEGF family members and receptors in coronary vessel formation

The specific roles of vascular endothelial growth factor (VEGF) family members and their receptors (VEGFRs) in coronary vessel formation were studied. By using the quail heart explant model, we found that neutralizing antibodies to VEGF‐B or VEGF‐C inhibited tube formation on the collagen gel more than anti–VEGF‐A. Soluble VEGFR‐1, a receptor for VEGF‐A and ‐B, inhibited tube formation by 87%, a finding consistent with that of VEGF‐B inhibition. In contrast, addition of soluble VEGFR‐2, a receptor for VEGF family members A, C, D, and E, inhibited tube formation by only 43%. Acidic FGF‐induced tube formation dependency on VEGF was demonstrated by the attenuating effect of a soluble VEGFR‐1 and ‐2 chimera. The localization of VEGF R‐2 and R‐3 was demonstrated by in situ hybridization of serial sections, which documented marked accumulations of transcripts for both receptors at the base of the truncus arteriosus coinciding with the temporal and spatial formation of the coronary arteries by means of ingrowth of capillary plexuses. This finding suggests that both VEGFR‐2 and R‐3 may play a role in the formation of the coronary artery roots. In summary, these experiments document a role for multiple members of the VEGF family and their receptors in formation of the coronary vascular bed.

Decreased expression of the c-kit receptor is associated with increased apoptosis in subfertile human testes

OBJECTIVE To examine the expression of the c-kit receptor and its ligand, stem cell factor, and their possible relation with apoptosis in infertile men. DESIGN Prospective laboratory study. SETTING Urology laboratory in a university hospital. PATIENT(S) Men undergoing testicular biopsy during an investigation of subfertility. INTERVENTION(S) None. MAIN OUTCOME MEASURE(S) Expression of the c-kit receptor protein, stem cell factor, and apoptosis in the testes. RESULT(S) The c-kit receptor was strongly present in Leydig cells and type A spermatogonia of normal testes, with decreased staining in Leydig cells and type A spermatogonia of testes with maturational arrest, and staining in only Leydig cells of Sertoli cell-only specimens. Stem cell factor was demonstrated in Leydig cells and Sertoli cells in all specimens. Western blotting demonstrated the 150-kd c-kit protein in the normal testes and the testes with maturational arrest, but not in the testes with the Sertoli cell-only pattern. Stem cell factor was expressed in all specimens, with a protein size of 45 kd. Increased apoptosis was demonstrated in type A spermatogonia and spermatocytes of tissue with maturational arrest compared with normal testicular tissue. CONCLUSION(S) C-kit receptor expression is decreased in subfertile testicular tissue compared with normal testicular tissue. Stem cell factor expression is present in Leydig cells and Sertoli cells. Increased apoptosis is seen in tissue with maturational arrest compared with normal tissue.

Early Coronary Angiogenesis in Response to Thyroxine Growth Characteristics and Upregulation of Basic Fibroblast Growth Factor

Although a substantial coronary angiogenesis occurs after thyroid hormone treatment, its regulation and relationship to cardiac hypertrophy are not understood. This study was designed to determine (1) the onset of capillary proliferation, (2) the sites of capillary proliferation, and (3) whether basic fibroblast growth factor (bFGF) upregulation occurs in response to thyroxine administration. Male Sprague-Dawley rats were injected daily with L-thyroxine (T4, 0.2 mg/kg s.c.). Bromodeoxyuridine labeling of capillary endothelial cells increased during the first 24 hours of treatment and peaked after 2 days of treatment. Northern blot analysis revealed a slight increase in bFGF mRNA during this period, followed by a doubling of expression by 48 hours, at which time bFGF protein was also increased. In situ hybridization, used to localize bFGF mRNA, showed an increase in transcripts within 24 hours after T4. This enhancement was uniform in the epimyocardium and endomyocardium. Histochemical analysis (double staining for alkaline phosphatase and dipeptidyl peptidase) of frozen sections, used to discriminate capillary profiles as arteriolar and venular, respectively, showed that growth occurred in the latter, since the percentage of capillary profiles positive for dipeptidyl peptidase was higher than the control value after 4 days of T4 administration. These data indicate that in the thyroxine model of cardiac hypertrophy (1) capillary DNA synthesis occurs after a single injection of thyroxine, (2) capillary growth coincides with an upregulation in bFGF mRNA and increase in bFGF protein, and (3) proliferation occurs in the venular capillaries.

Coronary vascularization during development in the rat and its relationship to basic fibroblast growth factor

OBJECTIVE Our overall aims were to elucidate the temporal and spatial sequence of coronary vascularization during development in the rat, and to determine whether basic fibroblast growth factor expression corresponds to any phase of the vascularization process. METHODS Immunohistochemical, histochemical, morphometric and in situ hybridization analyses were performed on prenatal and postnatal hearts of various ages. RESULTS Coronary vascularization, which begins at embryonic day 13 (E13) with blood island-like structures in the epicardium, progresses from this layer toward the endocardium as indicated by a transmural gradient of vascular volume throughout the ventricles. Vascular smooth muscle first appears in E17 hearts at the time a capillary-like plexus coalesces and penetrates the aorta to form the main coronary arteries. These vessels maintain an anastomatic morphology and must undergo subsequent remodeling in order to assume adult branching characteristics. The early postnatal period is characterized by development of the arterial tree and the enzymatic differentiation of the arteriolar and venular ends of the capillary bed. Although bFGF is expressed both prenatally and postnatally, the highest mRNA expression was noted during the early period of vascularization (E14 and E15), and the early neonatal period (1-6 days) which corresponds to a period of substantial microvascular growth. CONCLUSIONS Coronary vascularization follows a temporal sequence which includes transmural expansion of the capillary bed, arteriolar formation subsequent to vascular penetration of the aorta, and postnatal growth, differentiation, and remodeling. Since high levels of bFGF expression are correlated with key time points in coronary vascular growth, bFGF may play an important role in this process.

Localization and expression of the c-kit receptor protein in human and rodent testis and sperm.

OBJECTIVES To examine the localization and expression of the c-kit receptor protein in the testes of the mouse, rat, and human, and then compare these among the three species. METHODS Testis tissue from all three species was obtained through biopsy or orchiectomy. Immunohistochemistry was used for the localization, using a monoclonal antibody to the c-kit receptor. The expression of the c-kit receptor protein was examined in the testes and sperm with Western blot analysis. RESULTS Localization was noted in the early spermatogenic cells, most likely type A spermatogonia, as well as in the acrosomal region of more mature germ cells, such as the round spermatids. The c-kit receptor was localized in analogous sites in all three species. The Western blot data revealed testicular expression of the c-kit receptor protein in all three species as well. Similar bands were recognized on the Western blots of all three species in testes at approximately 75 kDa and approximately 90 kDa, and sperm at approximately 90 kDa only. CONCLUSIONS The c-kit receptor protein is expressed in the early spermatogenic cells, as well as the later stages of spermatogenesis, specifically, the acrosomal granules of the round spermatids, and the acrosomal region of testicular spermatozoa, in the mouse, rat, and human. All three species exhibit similar expression of the c-kit receptor protein in both testis and sperm, although to a varying degree. We believe that these observations allow direct valid comparisons concerning the expression of the c-kit receptor to be made cautiously to the human condition from experimental data obtained from rodents.

The C‐kit receptor and its possible signaling transduction pathway in mouse spermatozoa

The presence and role of the c‐kit protein was investigated in the mature sperm of the mouse. The c‐kit monoclonal antibody (mAb) ACK2 reacted specifically with the acrosomal region and the principal piece of fixed noncapacitated sperm but did not react with the acrosome region in acrosome‐reacted sperm. ACK2 significantly inhibited the acrosome reaction; this inhibition was relieved by the calcium ionophore A23187. The kit ligand stem cell factor (SCF) significantly increased the percentage of sperm undergoing acrosome reaction. This increase was partially inhibited by the calcium channel inhibitor (verapamil), the PI3k inhibitor (wortmannin), and the PLC inhibitor (U‐73122). ACK2 predominantly recognized c‐kit proteins of 33, 48, and 150 kDa by Western blotting of mouse sperm extracts. The 48‐ and 150‐kDa protein bands were released into the media and tyrosine autophosphorylated at low basal levels during acrosome reaction. On stimulation with SCF, the level of c‐kit phosphorylation increased significantly. These findings suggest that c‐kit is present in mature sperm, and its binding to SCF may result in the activation of PLCγ1 and PI3K, leading to receptor autophosphorylation, and ultimately may play a role in capacitation and/or the acrosome reaction. Mol. Reprod. Dev. 49:317–326, 1998.

Vascular transport of insulin to rat cardiac muscle. Central role of the capillary endothelium.

Using intact, beating hearts, we have assessed the interaction of insulin with capillary endothelium and the subsequent appearance of insulin in cardiac muscle. Rat hearts were perfused with 125I-insulin (10(-10) M) alone or in combination with unlabeled insulin (10(-9)-10(-5) M). 125I grains (shown to represent greater than 90% intact insulin) over both capillary endothelium and cardiac muscle decreased in a dose-dependent manner when hearts were co-perfused with labeled insulin and increasing concentrations of unlabeled insulin. Perfusion of 125I-desoctapeptide (DOP) insulin, a low affinity insulin analogue, with unlabeled insulin (10(-9)-10(-5) M) had no effect on the appearance of 125I-DOP insulin over microvessel endothelium and muscle. When capillary receptors were first destroyed by trypsin treatment or blocked by anti-receptor antibodies, the appearance of 125I-insulin in cardiac muscle decreased proportional to the inhibition of insulin binding to the capillary receptors. We conclude that insulin binding to capillary endothelial receptors is a central step in the transport of intravascular insulin to rat cardiac muscle.