Noel N. Kim

Arginase-boronic acid complex highlights a physiological role in erectile function.

The crystal structure of the complex between the binuclear manganese metalloenzyme arginase and the boronic acid analog of L-arginine, 2(S)-amino-6-boronohexanoic acid (ABH), has been determined at 1.7 Å resolution from a crystal perfectly twinned by hemihedry. ABH binds as the tetrahedral boronate anion, with one hydroxyl oxygen symmetrically bridging the binuclear manganese cluster and a second hydroxyl oxygen coordinating to Mn2+A. This binding mode mimics the transition state of a metal-activated hydroxide mechanism. This transition state structure differs from that occurring in NO biosynthesis, thereby explaining why ABH does not inhibit NO synthase. We also show that arginase activity is present in the penis. Accordingly, the tight binding and specificity of ABH allows us to probe the physiological role of arginase in modulating the NO-dependent smooth muscle relaxation required for erection. Strikingly, ABH causes significant enhancement of nonadrenergic, noncholinergic nerve-mediated relaxation of penile corpus cavernosum smooth muscle, suggesting that arginase inhibition sustains L-arginine concentrations for NO synthase activity. Therefore, human penile arginase is a potential target for therapeutic intervention in the treatment of erectile dysfunction.

Sildenafil Citrate, a Selective Phosphodiesterase Type 5 Inhibitor:: Research and Clinical Implications in Erectile Dysfunction

Under normal physiological conditions, following sexual stimulation, release of nitric oxide (NO) from penile non-adrenergic, non-cholinergic nerves and the endothelium activates guanylyl cyclase and induces intracellular cGMP synthesis in erectile tissue trabecular smooth muscle cells. Increased cGMP levels reduce intracellular Ca2+ concentrations, inhibiting smooth muscle contractility and thereby initiating the erectile response. Phosphodiesterase type 5 (PDE type 5) is the predominant enzyme responsible for cGMP hydrolysis in trabecular smooth muscle. Activation of PDE type 5 terminates NO-induced, cGMP-mediated smooth muscle relaxation, resulting ultimately in restoration of basal smooth muscle contractility and penile flaccidity. Sildenafil citrate is a potent PDE type 5 reversible and selective inhibitor that blocks cGMP hydrolysis effectively (Ki approximately 3 nM). Under conditions of excessive adrenergic tone or impaired neurovascular status, following sexual stimulation, sildenafil acts to enhance NO-mediated smooth muscle relaxation, resulting in improved penile erection in men with erectile dysfunction. In this review, we summarize the current state of knowledge of the physiology of penile erection and the pharmacology, metabolism and clinical experience with sildenafil citrate in the management of erectile dysfunction.

Human Arginase II: Crystal Structure and Physiological Role in Male and Female Sexual Arousal†,‡

Arginase is a binuclear manganese metalloenzyme that catalyzes the hydrolysis of l-arginine to form l-ornithine and urea. The X-ray crystal structure of a fully active, truncated form of human arginase II complexed with a boronic acid transition state analogue inhibitor has been determined at 2.7 A resolution. This structure is consistent with the hydrolysis of l-arginine through a metal-activated hydroxide mechanism. Given that human arginase II appears to play a role in regulating l-arginine bioavailability to NO synthase in human penile corpus cavernosum smooth muscle, the inhibition of human arginase II is a potential new strategy for the treatment of erectile dysfunction [Kim, N. N., Cox, J. D., Baggio, R. F., Emig, F. A., Mistry, S., Harper, S. L., Speicher, D. W., Morris, S. M., Ash, D. E., Traish, A. M., and Christianson, D. W. (2001) Biochemistry 40, 2678-2688]. Since NO synthase is found in human clitoral corpus cavernosum and vagina, we hypothesized that human arginase II is similarly present in these tissues and functions to regulate l-arginine bioavailability to NO synthase. Accordingly, hemodynamic studies conducted with a boronic acid arginase inhibitor in vivo are summarized, suggesting that the extrahepatic arginase plays a role in both male and female sexual arousal. Therefore, arginase II is a potential target for the treatment of male and female sexual arousal disorders.

Effects of ovariectomy and steroid hormones on vaginal smooth muscle contractility

The role of steroid hormones in regulating vaginal smooth muscle contractility was investigated. Rabbits were kept intact or ovariectomized. After 2 weeks, animals were continuously infused with vehicle or supraphysiological levels of testosterone (100 μg/day), or estradiol (200 μg/day), for an additional 2 weeks. The distal vaginal tissue was used to assess contractility in organ baths and changes in tissue structure were assessed by histology. Ovariectomized animals infused with vehicle exhibited significant atrophy of the muscularis and decreased epithelial height, resulting in thinning of the vaginal wall. Estradiol infusion increased epithelial height, comparable to that of intact animals, but only partially restored the muscularis layer. In contrast, testosterone infusion completely restored the muscularis layer, but only partially restored the epithelial height. In vaginal tissue strips contracted with norepinephrine and treated with bretylium, electrical field stimulation (EFS) caused frequency-dependent relaxation that was slightly attenuated with vehicle, significantly inhibited with estradiol and significantly enhanced with testosterone. VIP-induced relaxation was slightly attenuated in tissues from vehicle and estradiol-infused groups, but was enhanced in tissues from testosterone-infused animals. Contraction elicited by EFS or exogenous norepinephrine was not significantly altered with ovariectomy or steroid hormone infusion when data were normalized to potassium contraction. However, the tissue from testosterone-infused animals developed significantly greater contractile force to norepinephrine. These observations suggest that steroid hormones may be important regulators of vaginal tissue structure and contractility.

Biology of female sexual function

Although the psychosocial and relationship aspects of female sexuality have been extensively investigated, studies concerning the anatomy, physiology and pathophysiology of female sexual function and dysfunction are limited. The paucity of biologic data may be attributed to a lack of reliable experimental models and tools for investigating female sexual function and to limited funding, which is critical for developing experimental approaches. Research efforts by several investigators in different laboratories have been establishing experimental models needed for investigating the physiologic mechanisms involved in the genital arousal response of sexual function. These experimental models have permitted assessment of genital hemodynamics, vaginal lubrication, regulation of genital smooth muscle contractility and signaling pathways, providing preliminary information about the role of neurotransmitters and sex steroid hormones in sexual function. Further research is needed to define the neurotransmitters responsible for vaginal smooth muscle relaxation and the role of sex steroid hormones and their receptors in modulating genital hemodynamics, smooth muscle contractility, and neurotransmitter receptor expression. Finally, a global and integral understanding of the biologic aspects of female sexual function requires investigation of the vascular, neurologic (central and peripheral), and structural components of this extremely complex physiologic process.

Biochemical Factors Modulating Female Genital Sexual Arousal Physiology

INTRODUCTION Female genital sexual arousal responses are complex neurophysiological processes consisting of central and peripheral components that occur following sexual stimulation. The peripheral responses in sexual arousal include genital vasocongestion, engorgement and lubrication resulting from a surge of vaginal and clitoral blood flow. These hemodynamic events are mediated by a host of neurotransmitters and vasoactive agents. AIM To discuss the role of various biochemical factors modulating female genital sexual arousal responses. METHODS A comprehensive literature review was conducted using the PubMed database and citations were selected, based on topical relevance, and examined for study methodology and major findings. MAIN OUTCOME MEASURES Data from peer-reviewed publications. RESULTS Adrenergic as well as non-adrenergic non-cholinergic neurotransmitters play an important role in regulating genital physiological responses by mediating vascular and non-vascular smooth muscle contractility. Vasoactive peptides and neuropeptides also modulate genital sexual responses by regulating vascular and non-vascular smooth muscle cells and epithelial function. The endocrine milieu, particularly sex steroid hormones, is critical in the maintenance of tissue structure and function. Reduced levels of estrogens and androgen are associated with dramatic alterations in genital tissue structure, including the nerve network, as well as the response to physiological modulators. Furthermore, estrogen and androgen deficiency is associated with reduced expression of sex steroid receptors and most importantly with attenuated genital blood flow and lubrication in response to pelvic nerve stimulation. CONCLUSIONS This article provides an integrated framework describing the physiological and molecular basis of various pathophysiological conditions associated with female genital sexual arousal dysfunction.

Role of the nitric oxide-cyclic GMP pathway in regulation of vaginal blood flow

The regulatory role of nitric oxide (NO) in vaginal perfusion remains unclear. We used specific inhibitors of enzymes in the NO-cyclic GMP (NO-cGMP) pathway and investigated their effects on vaginal blood flow in the rabbit. NO synthase (NOS) activity was similar in both the proximal and distal rabbit vagina; whereas, arginase activity was 3.4-fold higher in the distal vagina. Intravenous administration of the NOS inhibitor L-NAME resulted in a 66% reduction in genital tissue oxyhemoglobin and a 53% reduction in vaginal blood flow. This attenuation occurred despite a 20–30% increase in systemic arterial pressure. The arginase inhibitor ABH caused a 2.1-fold increase in genital tissue oxyhemoglobin and 34% increase in vaginal blood flow. The guanylate cyclase inhibitor 1H-[1,2,4]oxadiazolo[4,3,-a]quinoxalin-1-one and the phosphodiesterase type 5 inhibitor sildenafil caused in a 37% reduction and a 44% increase in vaginal blood flow, respectively. These observations suggest that the NO-cGMP pathway is an important regulator of vaginal hemodynamics.

Streptozotocin-induced diabetes in the rat is associated with changes in vaginal hemodynamics, morphology and biochemical markers

BackgroundDiabetes is associated with declining sexual function in women. However, the effects of diabetes on genital tissue structure, innervation and function remains poorly characterized. In control and streptozotocin-treated female rats, we investigated the effects of diabetes on vaginal blood flow, tissue morphology, and expression of arginase I, endothelial nitric oxide synthase (eNOS) and cGMP-dependent protein kinase (PKG), key enzymes that regulate smooth muscle relaxation. We further related these changes with estrogen receptor alpha (ERα) and androgen receptor (AR) expression.ResultsIn addition to significantly elevated blood glucose levels, diabetic rats had decreased mean body weight, lower levels of plasma estradiol, and higher plasma testosterone concentration, compared to age-matched controls. Eight weeks after administration of buffer (control) or 65 mg/kg of streptozotocin (diabetic), the vaginal blood flow response to pelvic nerve stimulation was significantly reduced in diabetic rats. Histological examination of vaginal tissue from diabetic animals showed reduced epithelial thickness and atrophy of the muscularis layer. Diabetic animals also had reduced vaginal levels of eNOS and arginase I, but elevated levels of PKG, as assessed by Western blot analyses. These alterations were accompanied by a reduction in both ERα and AR in nuclear extracts of vaginal tissue from diabetic animals.ConclusionIn ovariectomized (estrogen deficient) animals, previous reports from our lab and others have documented changes in blood flow, tissue structure, ERα, arginase I and eNOS that parallel those observed in diabetic rats. We hypothesize that diabetes may lead to multiple disruptions in sex steroid hormone synthesis, metabolism and action. These pathological events may cause dramatic changes in tissue structure and key enzymes that regulate cell growth and smooth muscle contractility, ultimately affecting the genital response during sexual arousal.

Testosterone Increases Blood Flow and Expression of Androgen and Estrogen Receptors in the Rat Vagina

INTRODUCTION The mechanisms by which testosterone modulates female genital sexual arousal responses are poorly understood. AIM To investigate the effects of testosterone on vaginal blood flow and the expression of estrogen and androgen receptor proteins in the rat vagina. METHODS Mature female Sprague-Dawley rats were sham-operated (intact) or ovariectomized. Fourteen days after ovariectomy, animals were continuously infused with vehicle or varying doses of testosterone (5.5-55 microg/day). After 2 weeks of treatment, vaginal blood flow in response to pelvic nerve stimulation was measured by laser Doppler flowmetry. Plasma levels of testosterone and estradiol were determined by radioimmunoassay and epithelial thickness was examined in fixed vaginal tissue sections. Androgen and estrogen receptor levels were assessed by equilibrium radioligand binding and by Western blot analyses. RESULTS Vaginal blood flow responses were significantly reduced in ovariectomized rats and normalized in animals infused with testosterone. Ovariectomy increased the expression of estrogen receptors and reduced the expression of androgen receptors with no change in receptor-ligand affinity. Testosterone increased the expression of both androgen and estrogen receptors in the vagina. While physiological (11 microg/day) and supraphysiological (55 microg/day) concentrations of testosterone normalized vaginal tissue weight, uterine tissue and whole body weights were not significantly different from ovariectomized rats infused with vehicle. Testosterone infusion, even at supraphysiological concentrations, did not change plasma estradiol levels when compared to vehicle-infused, ovariectomized rats. Likewise, the vaginal epithelium of testosterone-infused rats remained atrophic, similar to vehicle-infused, ovariectomized rats, indicating that testosterone is not aromatized to estrogens at significant levels in the vagina. CONCLUSIONS Our data suggest that testosterone regulates androgen and estrogen receptor protein expression in the vagina and enhances vaginal perfusion by an androgen-dependent mechanism. We conclude that testosterone plays an important role in modulating the physiology of the vagina and contributes to improvement of genital sexual arousal responses.

Androgen Replacement Therapy with Dehydroepiandrosterone for Androgen Insufficiency and Female Sexual Dysfunction: Androgen and Questionnaire Results

During our evaluations of women with sexual dysfunction, we have seen many with low interest, arousal, and orgasmic capabilities with associated personal distress and diminished genital sensation and blood flow following sexual stimulation. Laboratory evaluation of these women has revealed normal estrogen but androgen values that were either below or in the lower quartile of the physiologic range. Androgen insufficiency and sexual dysfunction have been the working diagnoses in these women. Although many treatment options currently are available for this syndrome, there are limited data concerning safety and efficacy. The aim of this retrospective, Institutional Review Board (IRB)-approved, single-institution study was to report on the androgen and questionnaire results from a series of patients who underwent androgen replacement therapy with dehydroepiandrosterone for treatment of androgen insufficiency and sexual dysfunction. This study revealed that there was a significant decrease in sexual distress, a significant increase in sexual function in the domains of desire, arousal, lubrication, satisfaction, and orgasm, and a normalization to values within the physiologic range in the following androgens measured: total testosterone, free or bioavilable testosterone, DHEA, DHEA-S, and androstenedione. Side effects included increased facial hair (11%), weight gain (7%), acne (5%), temporary breast tenderness (1%), loss of head hair (1%) and skin rash (1%). Preliminary results suggest that androgen replacement therapy with dehydroepiandrosterone is a safe and effective treatment for androgen insufficiency and female sexual dysfunction. However, further research is needed, including prospective, multi-institution, placebo-controlled doubleblind studies.