Nilsa Patritti Laborde scite author profile

Epidermal growth factor (EGF) was originally isolated from mouse submandibular glands (SMG). However, SMG removal failed to lower circulating EGF, and large amounts of EGF have been found in mouse urine. In addition, the presence of pre-pro-EGF mRNA in mouse kidney has recently been reported by others. Kidneys may therefore represent an alternate source of EGF. In the present study, we investigated the immunocytochemical localization of EGF in mouse kidney. Male and female adult Swiss Webster mice were fixed by perfusion with 4% paraformaldehyde or Zamboni's fixative, the kidneys were frozen, and serial sections were obtained. Rabbit EGF antiserum was used for the primary incubation and the avidin-biotin complex immunoperoxidase procedure was utilized for immunostaining. EGF was immunolocalized in the apical portion of the cells lining the thick ascending limb of Henle (TALH) and the distal convoluted tubule (DCT). The macula densa, in contrast, lacked EGF immunoreactivity. No sex differences were observed in the distribution pattern or intensity of immunostaining. Infusion of EGF into sheep renal artery has been reported to induce changes in urine flow and ionic composition. Immunolocalization of EGF in the TALH and DCT documented here supports a regulatory role for EGF in the function of the mouse distal nephron.

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The source of urinary epidermal growth factor in humans

Callegari¹,

Laborde

Buenaflor³

et al. 1988

Europ. J. Appl. Physiol.

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To clarify the source of human urine EGF, we studied EGF renal clearance in 20 healthy, young adult subjects. Immunoreactive EGF was measured hourly in EDTA plasma, heparin plasma, serum and urine of 12 males and 8 females during a 3 h study period. Plasma and urine creatinine and creatinine clearance were measured and calculated hourly. Mean (and SEM) creatinine clearance was similar in males and females (118 +/- 12 vs 105 +/- 6 ml/min). EGF was not detectable in plasma, whereas relatively high levels were measured in serum (2.5 +/- 0.25 vs 1.5 +/- 0.18 ng/ml in males and females respectively p less than 0.05). Urine EGF excretion averaged 1641 +/- 233 ng/h in males and 1507 +/- 191 ng/h in females (p greater than 0.05). A significant correlation was observed between urine creatinine and urine EGF concentrations in both male (r = 0.98, p less than 0.01) and female (r = 0.94, p less than 0.01) subjects. EGF immunoreactivity in urine and serum eluted from G-75 sephadex columns similarly to recombinant 6000 Mr hEGF. Urine excretion of EGF approximated 1.5 micrograms/h or 25 ng/mg creatine. The high concentrations of EGF found in urine in the face of non-detectable levels of EGF in plasma favor the hypothesis that EGF in urine is derived from kidney synthesis and secretion. The significant positive correlation between urine creatinine and urine EGF suggests a functional correlation between glomerular filtration and the process of tubular EGF excretion.

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Daily Variations of FSH, LH and Testosterone Response to Intravenous Luteinizing Hormone-Releasing Factor (LRF) in Normal Men

Schwarzstein

Laborde²,

Aparicio

et al. 1975

The Journal of Clinical Endocrinology & Metabolism

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The responses of FSH, LH and testosterone to acute stimulation with synthetic LRF were studied in 6 healthy, fertile men aged 33.4 plus or minus 1.6 yr (X plus or minus SE). Fifty mug of LRF were given, iv at 0600 h, 1200 h, 1800 h and 0000 h, at 1-week intervals, to all 6 volunteers simultaneously. Blood samples were collected by venipuncture before (-5 and 0 min) and 8, 16, 32, 64 and 128 min after LRF injection. Plasma levels of FSH, LH and testosterone were determined by double antibody radioimmunoassay techniques. The responses of FSH and LH to LRF injection showed a clear difference at the times studied. Maximal values were obtained at 0600 h and 1800 h while the response at noon was not significant for LH and absent for FSH. Testosterone secretion showed a clear-cut response to LRF in all the subjects. At three of the four studied times (0600 h, 1800 h, 000 h) plasma testosterone was already increased at 8 min reaching its maximum at 16 min and persisted high until the end of the study. The noon response reached its maximum at the end of the test period. The daily variations of FSH and LH responses to acute LRF stimulation should be taken into consideration in clinical practive and the increment in testosterone secretion makes this test a useful indicator for androgenic testicular reserve.

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Autoregulatory Control of Thyrotropin in Rabbits

1984

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Studies were designed to determine whether an autoregulation system exists for TSH in the rabbit. For this purpose, a species-specific RIA for rabbit TSH that does not cross-react with human (h) TSH was developed. Hypothyroid animals were studied at varying time periods up to 3 months after either surgical thyroidectomy or propylthiouracil (PTU) treatment. Highly purified hTSH was injected iv at doses of 0 (saline control), 0.1, 0.3, 1,3, and 10 micrograms into unanesthetized rabbits bearing chronically implanted Silastic catheters. Blood samples were obtained at -30, 0, 10, 20, 30, 60, 120, 180, 240, and 300 min and 24 h. Doses between 0.3 and 10 micrograms hTSH produced a prompt fall (10 min) in rabbit TSH in hypothyroid rabbits studied 8-21 days after thyroidectomy. The minimum dose of hTSH that significantly suppressed rabbit TSH was 0.3 micrograms. This dose produced a peak value of hTSH in rabbit serum of 1.3 +/- 0.1 (+/- SEM) ng/ml 10 min after injection, which translates into a bioassay potency of 2.0 microU/ml (close to the physiological level in humans). A dose-response relationship existed between the hTSH dose injected and the duration and magnitude of suppression of rabbit TSH. This response to TSH was specific; 10 micrograms hTSH produced no change in endogenous rabbit serum LH and, conversely, 10 IU hLH produced no change in rabbit serum TSH. In contrast to these striking effects in acute hypothyroid animals, hTSH produced no detectable suppression of rabbit TSH in animals that were hypothyroid for 2-3 months. The sensitivity of the autoregulatory system to the suppressive effects of exogenous hTSH decreased with increasing duration of hypothyroidism; a time-response relationship existed. We conclude that: 1) a sensitive and specific autoregulatory control system for TSH exists in the rabbit; and 2) as the duration of hypothyroidism increases, the sensitivity of the autoregulatory system to the suppressive effects of endogenous TSH changes.

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The Secretion of Progesterone During the Periovulatory Period in Women with Certified Ovulation

Laborde

Carril

Cheviakoff

et al. 1976

The Journal of Clinical Endocrinology & Metabolism

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A pre-LH peak rise of progesterone in peripheral blood has been found in 13 normal cycling women whose ovulation was confirmed by biopsy of the corpus luteum through serial determination of progesterone and LH performed every 8 h during the periovulatory period. The progesterone rise began as an average 22 h (16-40 h) prior to the LH peak. The maximal preovulatory rise took place 9.6 h (0-24 h) before the LH zenith, remaining low for approximately 17 h when an abrupt rise of progesterone took place. The progesterone peak was detected in the morning samples in 11 of 13 patients studied. The progesterone rise was always followed by an LH peak and the highest peak of progesterone was trailed by the highest LH peak in all the patients except one.

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