Effects of long-term GH-releasing factor administration on patterns of GH and LH secretion in growing female buffaloes (Bubalus bubalis)

Effect of exogenous growth-hormone-releasing factor on blood metabolites and minerals in late maturing buffalo heifers (Bubalus bubalis)

Previous studies have suggested that growth-hormone-releasing factor (GRF) enhanced growth and advanced puberty onset along with hormonal changes in buffalo heifers (Bubalus bubalis). However, it is not known to what extent exogenous GRF could influence blood metabolites and minerals to bring about puberty in buffalo heifers. Therefore, we planned to investigate the effect of exogenous bovine GRF (bGRF) on blood metabolites and minerals in buffalo heifers during a 3-month pre-treatment period, 9-month treatment period and 1-month post-treatment period. Six buffalo heifers were treated intravenously with bGRF (10 mug per 100 kg body weight) at 15-day interval for 9 months. Another six buffalo heifers of weight- and age-matched received requisite amount of vehicle (0.9% NaCl solution) during the same period. Exogenous bGRF enhanced (p < 0.01) plasma non-esterified fatty acids (NEFA) concentrations in treatment group when compared with control group during the treatment and post-treatment period, while plasma alpha-amino nitrogen (AAN) concentrations showed a decreasing trend (p < 0.05) in the treatment group when compared with the control group during the treatment and post-treatment periods. The plasma inorganic phosphorus (Pi) was found to be higher (p < 0.05) in the treatment group animals in comparison with the levels recorded in the control group animals during the treatment as well as post-treatment periods. However, there was no change (p > 0.05) in plasma glucose and calcium concentrations between the two groups. Plasma NEFA was found to be positively correlated with plasma growth hormone (GH); however, it was only significant for the treatment group (r = + 0.76; p < 0.05). Plasma AAN in the treatment group exhibited negative correlation with plasma GH (r = 0.72; p < 0.05), while plasma AAN and GH were recorded to be positively correlated in the control group (r = 0.47; p < 0.05). The present findings suggest that exogenous bGRF induces GH release that increases plasma NEFA and Pi and decreases AAN concentrations, which probably help to reach a certain physiological state that initiates events necessary for bringing about puberty in buffalo heifers.

Plasma growth hormone concentrations in female mithun (Bos frontalis) of different ages: relations with age and body weight

The role of growth hormone (GH) in postnatal somatic growth is well established. Its basal level and relation to growth performance in different age group mithun (Bos frontalis), a semiwild ruminant has not been characterized until now. To estimate the normal blood GH level and also to assess the influence of age and body weight (BW) on blood GH level in captive mithuns, a total of 65 female mithuns was divided into six age groups (group I, 0-6 months; group II, >6-12 months; group III, >1-2 years; group IV, >2-2.5 years; group V, >2.5-3.0 years and group VI, >3.0 years). Blood samples collected weekly for six consecutive weeks were assayed for GH. GH was also estimated in the samples collected from six growing mithuns at -60, -45, -30, -15, -10, -5 and 0 min prior to GH-releasing hormone (GHRH) administration for calculation of basal GH level and at 5, 10, 15, 30 min and thereafter at 15-min interval up to 8 h post-GHRH to assess blood GH response following GHRH administration in growing mithuns. For calculation of basal plasma GH in adult mithuns, GH was measured in blood samples collected at 30-min interval for 24 h from four animals. BW of all animals was recorded on two consecutive days per week and average of weekly BW was considered for growth rate calculation. It was found that both mean GH and GH per 100 kg BW between the age groups differ (p < 0.01). With increasing age and BW, GH and GH per 100 kg BW both decreased (p < 0.01). The age group with higher plasma GH and GH per 100 kg BW showed higher growth rates (r = 0.83 and 0.97 respectively). Interestingly, mean plasma GH for six consecutive weeks in all the groups showed much greater GH concentration (group I, 86.6 +/- 9.7 ng/ml to group VI 33.2 +/- 5 ng/ml) than reported in other species. Mean basal plasma GH calculated in growing and adult mithuns was 29.6 +/- 4.01 ng/ml and around 25 +/- 3.6 ng/ml respectively. The GH peak (444 +/- 21.3 ng/ml) was registered at 15 min post-GHRH administration in growing mithuns. In conclusion, age and BW influence plasma GH and GH per 100 kg BW but the latter is a better indicator of growth. The basal plasma GH and GH response to GHRH administration is six to eight and four to five times higher in mithun than in other species reported so far. An accurate assessment of the relationship between GH profiles and protein metabolism, proper receptor level study for GH action at the cellular level and the interaction of GH with other growth factors awaits better understanding of higher GH in this unique species.

Determination of effective dosage of GH-releasing factor for blood GH responses in mithun (Bos frontalis)

A study was undertaken to determine the effective dosage of GH-releasing hormone (GRF) required to produce blood GH response in mithun (Bos frontalis), a semi-wild ruminant species. For the purpose, 12 mithuns averaging 11.5 months of age and 146 kg body weight (BW) were randomly assigned to receive GRF (n = 12), administered at 0 (normal saline), 5, 10 and 20 mug per 100 kg BW. Blood samples were collected prior to and after GRF administration at -60, -45, -30, -15, -10, -5, 0 min and 5, 10, 15, 30 and thereafter, at 15-min interval up to 8 h post-GRF were assayed for plasma GH. For all the dosages, the pre-treatment GH concentrations and corresponding area under GH response curve (AUC) were similar (p > 0.05). The post-GRF plasma GH responses to different dosages of GRF viz. 5, 10 and 20 mug per 100 kg BW and corresponding AUCs were higher (p < 0.05) than those recorded in normal saline-treated controls. The GH responses to 10 and 20 mug GRF per 100 kg BW and corresponding AUCs were higher (p < 0.05) than those registered in mithuns administered with 5 mug GRF per 100 kg BW. Interestingly, post-GRF concentration of plasma GH and AUCs were not different for 10 and 20 mug GRF per 100 kg BW dosages. In all animals treated with GRF, a peak of GH was registered within 10 to 20 min post-GRF. Following 5 mug GRF per 100 kg BW, GH concentrations were maintained at higher level for 90 min post-GRF and thereafter became similar to that of controls and it was 435 min for 10 and 20 mug GRF per 100 kg BW dosages. In conclusion, our results suggest that 10 mug GRF per 100 kg BW is the dosage, which can be used for augmentation of mithun production.

Effects of growth hormone-releasing factor on growth hormone response, growth and feed conversion efficiency in buffalo heifers (Bubalus bubalis)

The aim of this study was to determine the benefits of growth hormone-releasing factor (GRF) on growth and feed conversion efficiency (FCE) in buffaloes. Twelve Murrah buffalo heifers (Bubalus bubalis) of mean age 24.8 months and mean body weight 302.4kg were divided into two groups (treatment and control) with six animals in each group. The buffaloes were given intravenous injections of bovine GRF (bGRF) at a dose rate of 10microg/100kg body weight or an equal volume of saline at 15-day intervals for a period of 9 months. Plasma growth hormone (GH) responses to bGRF challenge were measured in blood samples collected at 90-day intervals on days 1, 90, 180 and 270 and samples were taken at -60, -30, 0, +10, +20, +30, +60, +120 and +180min relative to bGRF injection. Blood samples were also collected weekly by jugular venepuncture for the quantification of plasma GH. The average growth rate (AGR) and FCE of all animals were recorded at 15-day intervals. Plasma GH concentrations increased (P=0.001) steadily following bGRF challenge, peaking 10-20min after challenge and declining to baseline by 180min. In the treatment group, there were no significant differences (P>0.05) in either the peak heights of the GH response or the area under the curve (AUC) of the GH response after bGRF challenge on any of the four occasions of intensive bleeding. There were overall increases in plasma GH concentrations (P<0.01), AGR (P<0.01) and FCE (P=0.05) in the treatment group compared with the control animals. The study showed that GH responsiveness to administration of bGRF at 15-day intervals over 9 months of treatment remained unchanged in buffalo heifers. Exogenous bGRF treatment for a long period can therefore enhance GH release leading to higher growth rates and better feed conversion efficiency in buffalo heifers.

Exogenous GH-releasing hormone increases GH and LH secretion in growing mithuns (Bos frontalis)

To investigate the effects of growth hormone-releasing hormone (GHRH) administration on the patterns of GH and LH secretion in growing female mithuns, 12 mithuns within the age group of 10-12 months of age were divided into two groups (treatment and control groups) of six each in such a way that average body weight between the groups did not differ significantly (P>0.05). Both the groups were administered i.v. either with synthetic bGHRH [bGHRH (1-44)-NH2] at 10 microg/100 kg body weight (treatment group) or equal volume of normal saline (control group). Blood samples collected prior to and after GHRH challenge at -60, -45, -30, -15, -10, -5 min and 5, 10, 15, 30 min, and thereafter, at an interval of 15 min up to 8 h post-injection were assayed for plasma GH and LH. Plasma progesterone was estimated in twice-a-week samples collected for six consecutive weeks preceding GHRH challenge to assess whether either group has begun ovarian cyclicity. Body weight of all animals was recorded once in a week during the period. A peak of GH was registered in all animals within 5-25 min post-GHRH administration with a mean peak of 443.5+/-25.32 ng/ml at 15 min post-administration, which was much higher than in any other bovines reported following GHRH challenge. The patterns of LH secretion were pulsatile in nature in both the groups. Interestingly, the hormone concentrations exhibited higher pulsatility with greater amplitude after GHRH challenge in GHRH-treated than in control mithuns. The GHRH-treated mithuns averaged 0.44 pulses/h (4 pulses/9 h) and the rate was 0.20/h (2 pulses/9 h) in controls. The rate of pulse frequency and amplitude differed significantly with time of sampling. The mean plasma LH levels after GHRH administration were significantly higher in treatment group than those recorded in control mithuns. The mean plasma progesterone was similar (P>0.05) in both the groups and no animal from either group had begun ovarian cycle. In conclusion, exogenous GHRH significantly increases plasma GH and also LH pulse frequency and amplitude with higher mean post-GHRH LH levels in growing mithuns suggesting thereby its possible use for enhancement of maturity process in this unique meat animal.

Effect of nutrient restriction on the somatotropes and substance P-immunoreactive cells in the pituitary of the female ovine fetus

The maternal environment affects fetal development and may influence the physiology of the adult. Fetal growth hormone (GH) is increased by maternal undernutrition but the mechanisms responsible are unknown. This study determined the effect of maternal undernutrition on the development of fetal pituitary somatotropes in the female. Ewes were grouped randomly into control (fed 100% of requirements) or nutrient restricted (fed 50%) from Days 28 to 78 of gestation. At Day 78, the ewes were killed and fetuses collected (Day 78 NR (nutrient restricted): n=6; Day 78C (control): n=6). Remaining ewes were realimented to 100% of nutritional requirements and were killed at Day 135 (Day 135 NR (nutrient restricted): n=6; Day 135 C (control): n=6). Somatotropes were visualized immunocytochemically and the size, mean density, total percentage and proportion colocalized with substance P were determined for each group. Nutrient restriction increased (p<0.01) the density of pituitary cells in Day 78 fetuses but this difference was no longer apparent by Day 135 after realimentation. The density and proportion of somatotropes were not different between treatment groups at Day 78 but were significantly (p<0.05) lower in the nutrient restricted Day 135 fetuses as compared to the Day 135 control animals. Somatotropes from restricted fetuses were significantly (p<0.001) larger at Day 78. Nutrient restriction increased the density (p<0.001) and percentage (p<0.05) of substance P-immunoreactive cells Day 135 fetuses. Similarly, the proportion of somatotropes that expressed substance P was significantly (p<0.05) increased by nutrient restriction in the Day 135 fetuses. Although nearly two thirds of substance P-immunoreactive cells co-expressed GH, there was no significant effect of treatment on this co-expression. Additional studies are required to determine if other components of the neuroendocrine GH axis are affected by this nutritional insult, if the alterations that we have observed, particularly in the tachykinin system, persist into adulthood and, importantly, what are the long-term consequences of an altered GH axis.

Twenty-four-hour secretion patterns of luteinizing hormone in mithuns (Bos frontalis)

A 24 h secretion pattern of luteinizing hormone (LH) was not available in mithun (Bos frontalis), a semi-wild ruminant. To characterize the 24 h LH profiles, six female mithun calves (age 7.8 +/- 0.5 months and 102.5 +/- 5.6 kg; group I) and six female mithuns averaging 25.4 months of age and 240 kg (group II) were selected from the National Research Centre on Mithun farm and were maintained in semi-intensive systems. Blood samples collected from all the animals at 30 min intervals for 24h were assayed for plasma LH. Plasma progesterone was also estimated in twice-a-week samples collected for 6-week period preceding each 24h sampling to assess whether any animal had begun ovarian cyclicity. The body weights of all animals were also recorded weekly during the 6-week period. LH patterns consisted of frequent pulses of varying amplitude. Luteinizing hormone pulses occurred at an average frequency of 0.28/h ( approximately 7 pulses/24 h) and 0.15/h ( approximately 3.5 pulses/24 h) for mithuns of groups II and I, respectively, the rate did not differ markedly among mithuns within each group but was significantly different between the groups. Similarly, the magnitude of LH secretory pulses did not vary among mithuns within the group but was significantly higher in group II than in group I animals. In group II, the LH peaks averaged 1.59 and 1.00 ng/ml in mithun having the highest and lowest LH peaks, respectively and the corresponding values for group I mithuns were 0.66 and 0.51ng/ml. Mithun with higher peak LH levels also had higher mean LH concentrations (P<0.05). The mithuns of group II had significantly higher plasma progesterone concentration (0.89 +/- 0.02 ng/ml) than those recorded in group I mithuns (0.26 +/- 0.01 ng/ml). Plasma progesterone profiles suggested that no animal reached puberty. In conclusion, there was higher LH secretion with higher pulsatility and greater amplitude in group II mithuns than exhibited in mithuns of group I and the prepubertal mithuns of group II were in approaching puberty, which were also indicated by their plasma progesterone profiles, critical body weight and age required to attain puberty, in addition to higher pulsatility of LH secretion.

Growth hormone-releasing factor (GRF) induced growth hormone advances puberty in female buffaloes

Exogenous bovine growth hormone-releasing factor (bGRF) at the dose rate of 10 microg/100 kg body weight was administered intravenously (i.v.) to six Murrah buffalo heifers as treatment group, while another six buffalo heifers served as control group which received the vehicle (0.9% NaCl solution) at an interval of 15 days for a period of 9 months to study the effect of bGRF on puberty onset associated with temporal hormonal changes in peri-pubertal buffalo heifers. Blood samples were collected at 3-day interval from all the animals during the experimental period and plasma harvested was assayed for growth hormonal (GH), luteinizing hormone (LH) and progesterone. The day that plasma progesterone was greater than 1.0 ng/ml for three consecutive sampling days was defined as the day of puberty. Exogenous bGRF administration increased (P = 0.02) plasma GH concentration in treatment group over control group during the treatment of bGRF as well as during the peri-pubertal period. Plasma progesterone concentrations increased transiently earlier (P = 0.05) by 58.5 days in bGRF-treated buffaloes than that in the control group. However, plasma LH concentrations were unaffected by the treatment of bGRF (P = 0.48). Both plasma GH and LH in the buffalo heifers increased (P < 0.01) over time preceding puberty and the higher hormonal concentrations were maintained during the onset of puberty, and thereafter, the concentrations of both the hormones declined (P < 0.05) after puberty. GH and LH were positively correlated both before puberty (r = +0.59 and +0.63; P < 0.05 for control and treatment group, respectively) and after puberty (r = +0.42 and +0.46; P < 0.05 for control and treatment group, respectively) indicating the interaction and/or close relationship of GH and LH in the mechanism of puberty in buffalo species.

Effects of long-term growth hormone-releasing factor treatment on growth, feed conversion efficiency and dry matter intake in growing female buffaloes (Bubalus bubalis)

Effects of long-term growth hormone-releasing factor (GRF) on growth performance, feed conversion efficiency (FCE) and dry matter intake (DMI) were studied in growing buffaloes. Twelve female Murrah buffaloes of 6-8 months of age were divided into two groups of six each on the basis of their body weights so that the average body weights of the groups did not differ (p > 0.05). Animals of each group were administered intravenously with either sterile distilled water (control group) or equal volume of GRF solution containing 10 mug GRF (1-44)-NH2/100 kg body weight (treatment group) at fortnight interval from week 6 (5-week pre-treatment period) for 36 weeks (weeks 6-42 treatment period). Thereafter a 10-week post-treatment period was added. All the animals were weighed consecutively 2 days in a week and the average body weight of the two observations in the week was thus considered for further calculation. Dry matter intake was recorded daily. Average daily gain, FCE and DMI/100 kg body weight were also calculated. Plasma progesterone was estimated in the samples collected twice a week at 3-4-day intervals to assess whether either group had begun ovarian cycles. It was found that ADG and FCE were higher (p < 0.01) in GRF-treated animals during treatment and even 10-week post-treatment period. Interestingly, total DMI was not different (p > 0.05) between the groups during treatment period but found to be lower in GRF treated animals during post-treatment period. The DMI/100 kg body weight was lower (p < 0.01) in GRF-treated animals during treatment and even after cessation of treatment for 10 weeks. The GRF administration for long-term increased (p < 0.05) plasma progesterone. Plasma progesterone concentrations suggest that no animal from either group reached puberty till the end of the experiment. In conclusion, repeated GRF administration for longer term decreased (p < 0.01) DMI/100 kg body weight and increased (p < 0.01) FCE and enabled the animals to grow faster.

Secretion patterns of growth hormone in growing captive mithuns (Bos frontalis)

A study was conducted in May 2003 to characterize plasma growth hormone (GH) pattern in growing mithuns (Bos frontalis), a rare semi-wild ruminant. Six mithun calves averaging 235 day of age and 124 kg were maintained in semi-intensive system and group-fed once daily. Animals gained at a mean rate of 0.54 kg/day, with individuals ranging from 0.34 to 0.66 kg/day. Blood samples collected at 15-minute intervals starting from 0600h for nine-hour period were assayed for plasma GH. Growth hormone patterns consisted of frequent pulses of varying amplitude. Growth hormone pulses occurred at an average frequency of 0.69/h, the rate did not differ markedly among mithuns nor hour of day. The magnitude of GH secretory pulses varied significantly among mithuns. Growth hormone peaks averaged 95.0 and 45.2 ng/ml in mithuns having the highest and lowest GH peaks, respectively. Peak and mean GH levels were associated positively (r=0.98, P<0.001) and both were associated negatively (r=-0.97 and -0.98, respectively; P<0.01) with rates of gain. Results from the study show that 1) GH peaks occur at frequent intervals throughout the sampling period and 2) alteration in GH levels and patterns are elicited more by pulse amplitude than frequency modulation.

Effects of long-term growth hormone-releasing factor administration on plasma growth hormone, luteinizing hormone and progesterone profiles in growing female buffaloes (Bubalus bubalis)

To investigate the effects of long-term growth hormone-releasing factor (GRF) administration on plasma growth hormone (GH), LH and progesterone and body weight gain in growing buffalo calves, 12 female Murrah buffaloes within the age group of 6-8 months of age were divided into two groups (treatment and control groups) of six each in such a way so that average body weights between the groups did not differ (p > 0.05). Control buffaloes were not given any hormonal treatment and treatment group buffaloes were treated with synthetic bovine GRF [bGRF (1-44)-NH(2)] at the rate of 10 microg/100 kg body weight intravenously at an interval of 15 days from week 6 (5-week pre-treatment period) till 18 injections were completed (week 6-42 treatment period) and thereafter, effect of exogenous GRF were observed for 10-week post-treatment period. Jugular blood samples were drawn twice a week at 3-4-day intervals for plasma GH, LH and progesterone quantification. Body weight of all animals was recorded twice a week. During pre-treatment period, mean plasma GH, LH and progesterone did not differ (p > 0.05) between the groups. But during treatment as well as post-treatment period, mean plasma GH levels were found to be significantly (p < 0.01) higher in treatment than control group of buffaloes. Administration of GRF for longer term sustained a higher level of plasma GH even after cessation of treatment. GRF-treated buffaloes attained higher (p < 0.01) body weight than the controls. Repeated GRF administration for long-term significantly (p < 0.01) increased plasma LH and progesterone. In conclusion, repeated long-term exogenous GRF administration induces and even enhances GH release without any sign of refractoriness. GRF may, therefore, be used to induce daily GH release without loss of responsiveness over an extended period of time in young growing female buffaloes and it may assist these animals to grow faster.