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Differential Effects of Superior and Inferior Spermatic Nerves on Testosterone Secretion and Spermatic Blood Flow in Cats¹

Instituto de Neurobiología, Serrano 669 (1414); Facultad de Ciencias Biomédicas, Universidad Austral (A.M.S.), Garay 125 (1063); and Instituto de Biologia y Medicina Experimental (E.V., E.C.), Obligado 2490 (1428), Buenos Aires, Argentina

Address all correspondence and requests for reprints to: Dr. Sara R. Chiocchio, Instituto de Neurobiología, Serrano 669 (1414), Buenos Aires, Argentina. E-mail: fuacta{at}ssdnet.com.ar

	Abstract

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It has been postulated that testosterone secretion is partially regulated by signals from the spermatic nerves. To further examine this hypothesis in vivo, the superior (SSN) or the inferior (ISN) spermatic nerves were stimulated electrically (varying intensity, 25 Hz, 0.2 msec, 10 min) in anesthetized cats, determining the testosterone concentration and the blood flow in the spermatic vein. In some additional experiments arterial blood was sampled, and norepinephrine (NE) output was calculated. Stimulation of the SSN (25–35 V) increased the testosterone concentration in spermatic vein blood (P < 0.01 compared with prestimulation levels). The response varied among animals, reaching a 50–100% increase in some animals, whereas in others it ranged from almost undetectable to more than 10 ng/100 g·min. Under the same experimental conditions, the NE output increased from 135.4 ± 99 to 1614.2 ± 347 pg/ml (P < 0.01), and spermatic blood flow decreased from 24.1 ± 1.42 to 20.2 ± 1.65 ml/min·100 g (P < 0.05) during nerve stimulation. By contrast, stimulation of the ISN (25–35 V) modified neither the testosterone concentration, the NE output, nor the blood flow in the spermatic vein. High intensity stimulation (36–70 V) of each spermatic nerve evoked different vascular and hormonal effects. SSN activation induced a marked decrease in spermatic blood flow during stimulation and an increase in the testosterone response, whereas ISN activation resulted only in an enhanced spermatic blood flow. Our results suggest that testosterone secretion, although mainly dependent on gonadotropin secretion, could be further regulated by neural inputs from the SSN acting directly or alternatively through changes in blood flow. It would appear that the SSN mainly supplies the vasoconstrictor fibers to the testis, whereas the ISN provides vasodilator fibers.

	Introduction

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THE MALE mammalian gonad receives both sensory and efferent innervation from the spinal ganglia and prevertebral plexuses. Fibers converge to the testis along two major pathways, the superior (SSN) and the inferior (ISN) spermatic nerves. The former runs from the mesenteric and renal plexuses alongside the testicular artery, whereas the ISN, originating in the pelvic and inferior mesenteric plexuses, accompanies the vas deferens and penetrates the epididymis (1, 2). In the rat, the ISN enters the testis through the inferior testicular ligament (3).

Since the initial description by Bell and McLean (4), it has been known that most testicular nerves are adrenergic. In the rat, catecholaminergic fibers have been described around capsular blood vessels (4), but adrenergic innervation of the parenchyma has not been detected in either this rodent (3) or the guinea pig (5). By contrast, in the testis of man, cat, and monkey, adrenergic fibers have been observed around intratesticular blood vessels, seminiferous tubules, and Leydig cells (2).

Immunocytochemical studies have shown a great variety of peptidergic neurotransmitters in the testis. Nerve fibers containing neuropeptide Y, vasoactive intestinal peptide (VIP), calcitonin gene-related peptide, and substance P, among others, have been described in the testicular capsule and around blood vessels (2, 3, 6, 7). In the cat testis, we recently observed numerous peptidergic fibers in close association with Leydig cells (unpublished).

In vivo studies have shown that testicular nerves may influence androgen secretion (8, 9, 10, 11). In the rat, bilateral section of the SSNs blocks the acute stress-induced rise of plasma testosterone (8), inhibits the hCG-stimulated androgen production, and decreases the number of testicular LH receptors (11).

Those observations suggest that testosterone secretion, although mainly dependent on gonadotropin secretion, could be further regulated by signals coming from the spermatic nerves. The present experiments examined this hypothesis in vivo in the cat, a species with richly innervated testis. Our experimental design was based on the simultaneous measurement of testosterone concentration and blood flow in the spermatic vein after electrical stimulation of either the SSN or ISN.

	Materials and Methods

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General
Experiments were performed on adult domestic male cats (2.5–4.0 kg). Animals were kept in individual cages, with food and water ad libitum during 15 days before the experiments. Food was withdrawn 12 h before surgery, but water was freely supplied. Cats were anesthetized with sodium pentobarbitone (40 mg/kg, ip). A tracheotomy was performed, and a tracheal tube was inserted. Anesthesia was maintained with the same anesthetic (4 mg/kg·h, iv) through a cannula inserted in the right femoral vein. Anesthetic level was monitored in spontaneously breathing animals by clinical signs and the carbon dioxide content of expired air. The percentage of expired carbon dioxide was kept constant (range, 0.3–0.7%), adjusting the anesthetic infusion rate. Under these conditions, mechanical stimulation of the skin did not elicit cardiovascular responses. The femoral cannula was also used to replace lost fluids, using either saline or blood derived from other cannulas in the same animal. Body temperature was kept at 37.5 ± 0.5 C by a heating pad controlled by a rectal temperature sensor. The bladder was continuously drained.

The experiments were performed in accordance with ethical guidelines for the care and use of animals for experiments, approved by the Government of Buenos Aires City (Health Secretariat, Expedient 89784/92), Argentina.

Preparation
A catheter was inserted in the right carotid artery and was connected to a blood pressure transducer (Statham Instruments, Oxnard, CA) providing a continuous record of blood pressure, respiratory rate, and heart rate. SILASTIC brand cannulas (Dow Corning, Midland, MI) were placed in the main left internal spermatic vein and in the jugular vein from the same side. Cats were then heparinized (Liquemine, Roche, Buenos Aires, Argentina; 75 µg/kg), and an extracorporeal shunt was established between those veins, using a three-way valve. The circuit allowed a continuous assessment of blood flow and hormonal concentrations in the spermatic vein. Blood was returned to the circulation through the right femoral cannula or was collected for hormonal assays (0.1–0.5 ml/sample) and packed cell volume controls. No significant variations in packed cell volume were observed during each experimental session. Blood samples were centrifuged at 1500 x g and 4 C, and the supernatants were stored at -70 C until assayed.

The animals were killed at the end of the experiments by the administration of an overdose of sodium pentobarbitone. On postmortem evaluation, the anatomical integrity of the testis was examined before it was removed, weighed, and immersed in Bouin fixative for routine histology. Only those animals without gross abnormalities of microscopic structures were included in the study.

Spermatic blood flow measurements
Spermatic venous blood flow (milliliters per min) was measured by recording the filling time of graduated pipettes (12) and was adjusted to 100 g testis (milliliters per min/100 g). The flow values of our cat population were well within the range reported for other animals species with other techniques (2). The spermatic blood flow does include both testicular and epididymal flow, as no ligation of the epididymal vessels was performed. However, as the epididymal contribution is minimal (13), we can assume that the measured values mainly represent the testicular blood flow.

In preliminary experiments the blood flow filling time values were identical to those measured by blood volume collected during a specified time. Both procedures detected equally well the changes induced by nerve stimulation (see Results).

Nerve stimulation
Bipolar electrodes, with an interelectrode distance of 10 mm, were placed on SSN or ISN. The electrodes were made of silver wire (0.5 mm in diameter), attached to an acrylic frame, and were placed on one of the spermatic nerves just before closing the extracorporeal circulation shunt. The SSN electrode was set along the spermatic pedicle, 3–4 cm below the entrance of the spermatic vein cannula. Thus, this electrode was closer to the testis than was the cannula. The ISN electrode was placed in the inguinal portion of the vas deferens. Tissues and electrodes were isolated with cellophane paper (3.5 x 1.5 cm) and covered with liquid paraffin-impregnated cotton swabs to avoid desiccation and mass stimulation through current spread. Nerves were stimulated using an arrangement of Tektronix, Inc. (Beaverton, OR) waveform and pulse generator units. Square pulses of 0.2-msec duration were delivered as a 25-Hz tetani through a constant voltage isolation unit. Using this arrangement, the delivered current was distributed among the nerve fibers (between electrode tips) and the rest of the body (in parallel with the intact nerve). To block the centripetal conduction of impulses produced by the electrical nerve stimulation, the proximal region of each nerve was infiltrated by 1% xylocaine solution (30–50 µl; Lidocaina, Astra, Buenos Aires, Argentina). The SSN was infiltrated near the insertion point of the spermatic vein cannula, whereas the ISN was infiltrated in its abdominal portion. Local nerve anesthesia was applied 10–15 mm cephalad to the electrode site and 10–15 min before electrical stimulation.

Only one given stimulus intensity was used in each animal. As most spermatic nerve fibers are unmyelinated (14), the experiments started with high voltage stimuli (70 V) to ensure activation of all nerve fibers innervating the testis. After preliminary experiments using high voltage, the SSN were stimulated with voltages varying randomly between 15–70 V in a series of cats (n = 17). This broad range of stimulus intensities was used to explore effects dependent on differential fiber excitability (i.e. according to diameter). Comparison of the hemodynamic and hormonal values obtained in these animals allowed sorting of the experiments into three groups according to the intensity of nerve stimulation: 1) low intensity (15–24 V) in which there were no effects, 2) medium intensity (25–35 V) with clear hormonal effects, and 3) high intensity (36–70 V) with both hormonal and blood flow effects. Then, another series of experiments (n = 11) was performed stimulating the ISN using the same voltage ranges described above. Sham-stimulated animals (n = 6) had SSN or ISN electrodes applied as described but received no stimulation.

To determine whether the hormonal effects evoked by SSN stimulation could be attributable to norepinephrine (NE) release from SSN nerve terminals, a separate series of experiments was conducted, stimulating the SSN or the ISN with medium intensities (25–35 V). Nine cats were studied under baseline conditions of barbiturate anesthesia, stable arterial pressure, and normoxia. The animals were equipped with iv catheters, as described previously, plus a polyethylene catheter inserted into the femoral artery with its tip lying close to the origin of the spermatic artery.

Hormonal analysis
Testosterone assays were directly made in predetermined plasma dilutions, using a solid phase RIA (Immunotech International, Dianova GmBH, Hamburg, Germany). The sensitivity of the method, defined as the minimal concentration of testosterone significantly different from 0 with a 95% probability, was 0.025 ng/ml. The cross-reactivity of the testosterone antiserum bound to the assay tubes was 0.01–1% for C₁₉ steroids and less than 0.03% for C₁₈ and C₂₁ steroids.

Plasma testosterone concentrations were corrected by packed cell volume to whole blood values. The product of testosterone concentration (nanograms per ml) in the spermatic vein blood and the spermatic blood flow at the time of collection was termed the corrected testosterone concentration (CTC) and was expressed as nanograms per 100 g/min.

NE in arterial and spermatic vein plasma was measured by HPLC with electrochemical detection after alumina extraction (15, 16). The assay was performed using a C₁₈ guard column and a C₁₈ Spherisorb reverse phase column (25 cm x 4.6 mm id) with a mobile phase (0.039 M citric acid, 0.10 M sodium acetate, 0.40 mM EDTA, and 0.20 mM sodium l-octyl sulfate, pH 4.2, containing 4.0% methanol) pumped at a flow rate of 1 ml/min (1600 psi). Under these conditions, the intraassay coefficient of variation for a spermatic venous plasma pool with a NE concentration of 1 ng/ml was 10% (n = 9). All samples were determined in the same assay. NE output was calculated as the venous-arterial blood concentration difference, multiplied by the blood flow at the time of collection and expressed as picograms per min.

Analysis of data
For each experimental animal, four consecutive observation periods were defined: PRE, 15 min before the onset of stimulation; ST, 10 min during stimulation; and P-1 and P-2, two periods of 15 min each after stimulation. In each experimental period, three to five samples for testosterone assay were obtained. Although all of the respiratory and cardiovascular parameters were measured continuously, only those spermatic blood flow values corresponding to the blood sample obtained for determination of testosterone were used for CTC calculation. All available CTC readings and cardiovascular parameters from each period were summarized as an arithmetic average.

For each intensity group, differences in CTC values from different experimental periods were analyzed via the Friedman global procedure for repeated measures, followed by Dunn’s test for the significance of pairwise comparisons (17). These are nonparametric procedures based on ranks, and therefore, results are independent of the actual variability between experimental units. Each cat was regarded as one experimental unit with four repeated observations (one per experimental period). Results were deemed significant if P < 0.05. Statistical analyses of spermatic blood flow and NE output responses to SSN and ISN stimulation were performed using ANOVA followed by Student-Newman-Keuls tests. Results are expressed as the mean and SE.

	Results

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Basal values
Basal values of spermatic blood flow and testosterone concentration in the spermatic vein are shown in Figs. 1 and 2, respectively. Within the sample, spermatic blood flow ranged between 20–64 ml/100 g·min (Fig. 1). The CTC values exhibited large individual variations, being as low as 0.013 ng/100 g·min in some animals and as high as 8000 ng/100 g·min in others (Fig. 2).

View larger version (15K): [in this window] [in a new window]   Figure 1. The spread of the basal values of spermatic blood flow (SBF) within our cat population (n = 42) is shown in this box plot. The line crossing the box represents the median, whereas the 25th, 10th, and 5th percentiles are represented by the lower box hinge, whisker, and dot, respectively. The 75th, 90th, and 95th percentiles are similarly represented in the upper part of the graph.

View larger version (18K): [in this window] [in a new window]   Figure 2. This box plot depicts the spread of basal values of CTC in the spermatic veins of our cat population (n = 42). The median and the percentiles are indicated as described in Fig. 1. Notice the exponential nature of the vertical axis.

View larger version (17K): [in this window] [in a new window]   Figure 3. A representative example of the simultaneous recording of mean arterial pressure (MAP), spermatic blood flow (SBF), and testosterone concentration corrected for blood flow (CTC) in a sham-stimulated cat. Although MAP and SBF remained stable, the CTC values fluctuated widely over the course of the experimental session.

View larger version (18K): [in this window] [in a new window]   Figure 4. Spermatic blood flow (SBF) in SSN-stimulated animals at low (A), medium (B), and high (C) intensities. In all of the histograms, the bars represent the average ± SEM of five or six animals at different periods: PRE, 15 min before stimulation; ST, 10 min during stimulation; and P-1 and P-2, consecutive 15-min periods after stimulation. A, No significant changes were detected after low intensity stimulation. B, There was a significant difference in SBF (*, P < 0.05) between PRE and any of the other periods. C, A significant decrease (**, P < 0.01) in SBF occurred during the stimulation period.

View larger version (20K): [in this window] [in a new window]   Figure 5. Spermatic blood flow (SBF) in ISN-stimulated animals at low (A) and high (B) intensities. In all of the histograms, the bars represent the average ± SEM of three (low) or six (high) animals at different periods. A, No significant changes were detected in animals receiving a low intensity stimulation of the ISN. B, An increase in SBF was observed during stimulation with high intensity stimuli. There was a significant statistical difference in SBF between ST and any of the other periods (*, P < 0.05).

View larger version (24K): [in this window] [in a new window]   Figure 6. Illustrations of the testosterone concentration corrected for blood flow (CTC) in response to stimulation of the SSN at medium (A–D) and high (E and F) intensities in individual cats. The horizontal bar in the top scale indicates the duration of stimulation.

ISN. CTC values did not change significantly in response to nerve stimulation (Table 4). In animals receiving low voltage stimulation, the CTC values slightly decreased during the second poststimulation period.

View larger version (22K): [in this window] [in a new window]   Figure 7. Effect of medium intensity stimulation of the SSN on the output of norepinephrine (NE) in the spermatic vein. Blood samples were collected and pooled before (PRE, 15 min), during (ST, 10 min), and after (P-1, 15 min) stimulation. Each column represents a mean of five values SEM. *, P < 0.05 vs. P-1; **, P < 0.01 vs. PRE.

	Discussion

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Low to medium intensity stimuli have been frequently used for stimulation of autonomic nerves. Higher intensity stimuli, which also have been used in the present study, were very useful for confirmation of the selective effects of each nerve. Although high voltage stimulation within a volume conductor, as in our experimental arrangement, could allow electrical current to spread beyond the electrode sites, opposite effects were obtained by activation of either the SSN or the ISN. These different results elicited by stimulation of each nerve indicate that isolation of the electrodes was efficient in avoiding the occurrence of virtual cathodes (in nerve fibers) in places outside of electrode location.

In the present study we show that SSN stimulation results in an increase in the testosterone concentration in the spermatic vein. Testosterone levels in the spermatic vein represent around 40–60% of the levels found in the testicular vein (18, 19). However, in a variety of mammals the testosterone secretion profiles in both veins are comparable (19).

It has been shown that under normal conditions, arterial-venous anastomoses in the pampiniform plexus provide arterial blood to the venous effluent of the testis diluting the testosterone concentration in the spermatic vein (2, 19). It could then be speculated that the rise in the concentration of testosterone is secondary to vasoconstriction of the spermatic artery (20) and probably of such anastomoses. However, a redistribution of blood flow in the spermatic vein by some nerve-induced constrictor mechanism need not be invoked. If this had occurred, it should have been observed as a drastic decrease in venous outflow and a minor increase in testosterone concentration during stimulation. In fact, there was only a minor drop in venous outflow and great changes in steroid concentration in the majority of the animals with medium intensity stimulation.

Increases in testosterone levels with SSN stimulation could also occur through other mechanisms. One possible explanation might be that nerve stimulation induces an increased access of LH to the testis by increasing testicular blood flow and thus inducing enhanced steroid secretion (2). This possibility seems unlikely, because in our experimental conditions, SSN stimulation evokes a slight reduction of the spermatic blood flow.

The increase in testosterone secretion could also be due to some other SSN-dependent rise of LH. Direct nerve connections between the testis and the hypothalamus have been described (21, 22, 23, 24), but in our experiments centripetal conduction was blocked by xylocaine anesthesia. On the other hand, preliminary LH determinations by RIA in cats (using a serum against bovine LH) showed that spermatic nerve stimulation did not induce changes in the plasma level of this gonadotropin.

The simultaneous increases in testosterone and NE output in the spermatic vein in response to SSN stimulation suggest the participation of the sympathetic innervation in the control of the endocrine function of the testis. Most probably, the increase in testosterone levels is a direct effect of NE release from SSN terminals on Leydig cells. Support for this hypothesis comes from several sources: 1) in vitro experiments demonstrate the ability of noradrenaline to enhance testicular steroidogenesis (25, 26, 27, 28, 29); 2) section of the SSN results in a decreased testosterone secretion in response to hCG (11); 3) similar results were obtained when the animals were chronically treated with guanethidine, an adrenergic blocking agent that causes a pharmacological sympathetic denervation (10); and 4) morphological evidence showing that the SSN provides the bulk of the adrenergic innervation to the testis (3).

As is well known, Leydig cell functions are under a complex control system including various endocrine, paracrine, and autocrine interactions (30). Therefore, it is also possible that NE and/or other neurotransmitters released from SSN terminals affect substances contained in other testicular cell types, which, in turn, act on Leydig cells to stimulate testosterone secretion. Whatever the exact mechanism may be, the present data support the view that increased superior spermatic neural input to the testis elevates testosterone levels in the spermatic vein.

Stimulation of each spermatic nerve induced a characteristic modification of the spermatic blood flow. This parameter decreased after stimulation of the SSN and increased after stimulation of the ISN. The extent of the spermatic blood flow modification depended on the intensity of the stimulus. As changes in spermatic blood flow took place under a steady mean arterial pressure, they probably represent modifications in vascular diameters induced by released neuromediators. NE is probably involved in the response to SSN stimulation, as it has been shown that intraarterial infusion of NE elicits a testicular vasoconstrictor response resembling the neurally induced response (31, 32). Moreover, lumbar sympathectomy causes a bilateral increase in testicular blood flow (32).

By contrast, spermatic blood flow increased with high intensity stimulation of the ISN. Several neurotransmitters and neuromodulators found in the ISN and in intratesticular nerves in the cat, including VIP, galanin, and calcitonin gene-related peptide (33), could be involved in this effect, as these substances exhibit strong vasodilatory properties. Our previous study in the rat demonstrated that VIP nerves fibers were present in the ISN but not in the SSN (3), and this distribution may also be present in the cat testis.

In conclusion, the present data demonstrate that each spermatic nerve differentially affects the spermatic testosterone concentrations and blood flow. The finding that SSN stimulation induces simultaneous rises in the testosterone concentration and NE output in the spermatic vein permits us to suggest that sympathetic inputs contribute to the control of plasma testosterone levels.

	Acknowledgments

 
It is a particular pleasure to acknowledge Dr. Armando Garsd for kindly reviewing the manuscript, Dr. Mauricio Rivera for measurement of norepinephrine, Med. Vet. Silvina Heisecke and Marcela Marquez and Mrs. Marcela Huerta for their expert technical assistance and Mr. Ignacio Fossati for preparation of the manuscript.

	Footnotes

 
¹ This work was supported by Consejo Nacional de Investigaciones Científicas y Técnicas and Fundación Instituto de Neurobiología (Buenos Aires, Argentina).

² Present address: East China Normal University, North Zhongshan Road 3662, Shangai, Peoples Republic of China 200062.

³ Present address: INSIBIO, Chacabuco 461, 4000 Tucuman, Argentina.

Received June 23, 1998.

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