M. Taneja

Aberrant patterns of X chromosome inactivation in bovine clones

In mammals, epigenetic marks on the X chromosomes are involved in dosage compensation. Specifically, they are required for X chromosome inactivation (XCI), the random transcriptional silencing of one of the two X chromosomes in female cells during late blastocyst development. During natural reproduction, both X chromosomes are active in the female zygote. In somatic-cell cloning, however, the cloned embryos receive one active (Xa) and one inactive (Xi) X chromosome from the donor cells. Patterns of XCIhave been reported normal in cloned mice, but have yet to be investigated in other species. We examined allele-specific expression of the X-linked monoamine oxidase type A (MAOA) gene and the expression of nine additional X-linked genes in nine cloned XX calves. We found aberrant expression patterns in nine of ten X-linked genes and hypomethylation of Xist in organs of deceased clones. Analysis of MAOA expression in bovine placentae from natural reproduction revealed imprinted XCI with preferential inactivation of the paternal X chromosome. In contrast, we found random XCI in placentae of the deceased clones but completely skewed XCI in that of live clones. Thus, incomplete nuclear reprogramming may generate abnormal epigenetic marks on the X chromosomes of cloned cattle, affecting both random and imprinted XCI.

Developmental Competence of Juvenile Calf Oocytes In Vitro and In Vivo: Influence of Donor Animal Variation and Repeated Gonadotropin Stimulation

Abstract Juvenile calf oocytes represent an untapped source of germ plasm for reproduction. Reports on the developmental competence of calf oocytes have been controversial. In this research, oocytes were recovered after gonadotropin stimulation from Holstein calves (N = 10) at 2–3 mo of age (2-mo cycle) and again at 4–5 mo of age (4-mo cycle). The in vitro developmental competence was measured, and prestimulation follicle numbers (for 2-mo cycle) and poststimulation follicle numbers (both cycles) were obtained. The number of antral follicles doubled after stimulation (23.4 ± 6.1 vs. 55.1 ± 16.1) for the 2-mo cycle and for the 4-mo cycle (47.4 ± 12.4). The number of follicles observed prior to stimulation in the 2-mo cycle was found to be highly correlated with the poststimulation oocyte recovery for both collection cycles (r = 0.95, 2-mo cycle; r = 0.81, 4-mo cycle). The majority (90–96%) of recovered oocytes were found to be usable for in vitro maturation and fertilization; of these, 41–42% cleaved and 10–11% developed to morulae or blastocysts. Eighty-four in vitro-produced embryos were transferred to synchronized recipients and resulted in 11 pregnancies, leading to 7 live (4 males, 3 females) and 2 dead (one male, one female) calves at full term. No significant differences were observed between the 2-mo and 4-mo collection cycles; however, 73% of the total pregnancies resulted from the 2-mo cycle. All pregnancies resulted from embryos of high-responding donors. The high correlation between the number of follicles prior to stimulation and the poststimulation response suggests the possibility of screening calves prior to stimulation for routine embryo production.

Control of oocyte maturation in cows--biological factors.

Since bovine in vitro fertilization became possible in the early 80s, a lot of effort has been done to clarify the mechanisms of what seems more and more one of the crucial steps in this procedure, being oocyte maturation. Undoubtedly, many biological factors act together to prepare the immature oocyte for a successful development to a competent embryo after fertilization. Defects in oocyte maturation can possibly be caused by an inadequate nuclear or cytoplasmic maturation or even by a failure of both. There is a general agreement upon the fact that the origin of the oocyte can play an important role. Oocytes derived from very small follicles show a lower rate of maturation and lower blastocyst development with currently used maturation protocols. Parthenogenetic activation of small size follicle derived oocytes suggests that their poor development was not caused by fertilization problems but more likely by intrinsic oocyte factors. Similar developmental rates achieved through nuclear transfer and parthenogenetic activation suggests that the nucleus of the incompetent oocyte may not be the sole reason for a poor development. Another important factor appears to be the donor animal age. The younger the donor animal, the more impaired is its oocytes developmental competence in most of the embryo IVP systems. Treatment with exogeneous gonadotropins can be beneficial in young donors on the oocyte cleavage rates but does not always increase the final blastocyst outcome. This review briefly documents some of the biological factors and their possible effects on the developmental capacities of the bovine oocyte in vitro.

Reproductive Characteristics of Cloned Heifers Derived from Adult Somatic Cells

Abstract This study examined the onset of puberty, follicular dynamics, reproductive hormone profiles, and ability to maintain pregnancy in cloned heifers produced by somatic cell nuclear transfer. Four adult somatic cell-cloned heifers, derived from a 13-yr-old Holstein cow, were compared to 4 individual age- and weight-matched heifers produced by artificial insemination (AI). From 7 to 9 mo of age, jugular venous blood samples were collected twice weekly, and from 10 to 11 or 12 mo of age, blood sampling was carried out every other day. After the heifers reached puberty (defined as the first of 3 consecutive blood samples with peripheral plasma progesterone concentrations of >1 ng/ml), ultrasound examination of ovaries and jugular plasma sample collection were carried out daily for 1 estrous cycle. Cloned heifers reached puberty later than controls (mean ± SEM, 314.7 ± 9.6 vs. 272 ± 4.4 days and 336.7 ± 13 vs. 302.8 ± 4.5 kg for clones and controls, respectively; P < 0.05). However, cloned and control heifers were not different in estrous cycle length, ovulatory follicle diameter, number of follicular waves, or profiles of hormonal changes (LH, FSH, estradiol, and progesterone). Three of the 4 clones and all 4 control heifers became pregnant after AI. These results demonstrate that clones from an aged adult have normal reproductive development.

COMPARISON OF VARIOUS MATURATION TREATMENTS ON IN VITRO MATURATION OF GOAT OOCYTES AND THEIR EARLY EMBRYONIC DEVELOPMENT AND CELL NUMBERS

In the present study, comparison of 2 different culture media (Hams F-12 and M-199) for supporting in vitro maturation of goat oocytes, and their subsequent embryonic development was evaluated in the presence or absence of sera (estrous goat serum, EGS and fetal calf serum, FCS) and hormones (FSH, 0.5 ug/ml, LH, 5 ug/ml and estradiol, 1 ug/ml). Neither medium (Hams F-12 or M-199) when supplemented with EGS and hormones showed any notable changes in the maturation rate nor in cleavage and blastocyst development. The mean cell number for blastocysts was also significantly low (P < 0.05). However, Hams F-12 medium supplemented with FCS and hormones showed a considerable increase in the maturation rate, but subsequent embryonic development was not appreciably increased. However, maturation, cleavage and blastocyst development rates of oocytes matured in M-199 medium in combination with 10% FCS and hormones were significantly higher (P < 0.05). Mean cell number per blastocyst was also significantly increased in this latter treatment compared with that of the other groups (P < 0.05). The results thus indicated that both the culture medium and serum have a marked effect on maturation and subsequent embryonic development. Further, the results also showed that the combination of M-199 with FSH, LH and E2 supplemented with 10% FCS was the most efficacious medium for in vitro maturation and subsequent embryonic development of the media, sera and hormone combinations studied.

Age-Related Changes of the Somatotropic Axis in Cloned Holstein Calves

Abstract To determine if the development of the somatotropic axis in somatic clones (clones) is similar to that in heifers produced by artificial insemination (controls), serum samples were collected every 30 min for 6 h, once per month, for 7 mo from 4 clones generated from a 13-yr-old cow and from 4 age-matched controls. Average concentrations of growth hormone (GH) were not different between clones and controls, and GH concentrations declined over time in controls. Average concentrations of insulin-like growth factor I (IGF-I) were less in clones than controls, and IGF-I concentrations increased over time in both groups. Concentrations of IGF-binding protein 3 (IGFBP-3) were greater in controls than in clones and did not change over time. Average IGFBP-2 concentrations did not change over time and were not different between clones and controls. Clones and controls were challenged with GH-releasing hormone (GHRH) (3 μg/100 kg body weight) and somatostatin (somatotropin release-inhibiting factor [SRIF]) (1.87 and 5 μg/100 kg body weight) at 14 mo of age. GHRH-induced GH secretion was greater and SRIF inhibition of GHRH-induced GH was less in clones than in controls. We speculate that some of the differences between clones and controls in concentrations of GH, IGF-I, and IGFBP-3 may be related to the genetic merit of the animals. Although there were differences in concentrations of components of the somatotropic axis between these clones and their age-matched controls, the values recorded were all within the range reported for calves of similar ages.

Morphological development, cell number, and allocation of cells to trophectoderm and inner cell mass of in vitro fertilized and parthenogenetically developed buffalo embryos: The effect of IGF-I

The morphology and number of cells in the trophectoderm (TE) and inner cell mass (ICM) of buffalo blastocysts derived from in vitro fertilization and cultured in the presence or absence of insulin‐like growth factor‐I (IGF‐I) were analyzed by differential fluorochrome staining technique. The total cell number (TCN), TE number, and ICM cell number were significantly higher in blastocysts developed in vitro in the presence of IGF‐I as compared to blastocysts developed without IGF‐I (P < 0.01). It was observed that the buffalo blastocyst took 5–9 days postfertilization to develop in vitro. In order to correlate the time required for blastocyst development and the allocation of cells to TE and ICM, blastocysts were designated as fast (developing on or before day 7) or slow (developing after day 7). The TCN, TE, and ICM cells of fast‐developing blastocysts cultured in the presence of IGF‐I were significantly higher than slow‐developing blastocysts (P < 0.01). The blastocysts developed on day 6 had a mean total cell number 118.6 ± 21.4, which significantly decreased to 85.6 ± 17.4, 62.0 ± 14.5, and 17.0 ± 4.0 on days 7, 8, and 9, respectively (P < 0.05). Normal development of buffalo embryo showed that, on average, embryos reached compact morula stage at the earliest between days 4.5–5.5. Blastocysts developed, at the earliest, between days 5.0–6.0, and it took them, on average, 6.5 days to hatch from the zona pellucida. TCN, TE, and ICM increased three times from morula to blastocyst; however, the proportion of ICM to TCN remained the same, in both embryonic stages. TE approximately doubled in hatched blastocysts, as compared to unhatched blastocysts (P < 0.05). However, ICM cells were decreased. The time required for development of parthenogenetic blastocysts was observed to be greater as compared to in vitro fertilized (IVF) blastocysts. The total cell number of parthenogenetic blastocysts was 100.8 ± 11.3, including 59.2 ± 8.4 cells of TE and 42.1 ± 6.9 cells of ICM.

Ovarian follicular dynamics in water buffalo

Abstract The pattern of growth and regression of ovarian follicles was characterized during 7 complete estrous cycles in 5 water buffalo by daily ultrasonographic examinations of the ovaries. Follicles ≥ 4 mm were measured and their relative locations within the ovary were determined to follow the sequential development of each individual follicle. Results indicated the presence of either one (n = 3 estrous cycles) or two (n = 4 estrous cycles) waves of follicular growth per cycle. Each wave was characterized by the development of 1 large (dominant) follicle and a variable number of smaller (nondominant) follicles. In the single follicular wave pattern, the wave started on Day 1.3 ± 0.7 (Mean ± SEM; estrus = Day 0). In the 2-wave pattern, first and the second waves started on Days 1.8 ± 0.6 and 7.8 ± 2.0, respectively, and the dominant follicle in the second wave was the ovulatory follicle. The maximal size and growth rate of the dominant follicle in the first and second wave of the 2-wave cycles did not differ significantly. However, the growth rate of the ovulatory dominant follicle in the 2-wave cycles was greater (P

Behavioral observations of adolescent Holstein heifers cloned from adult somatic cells

Cloning using somatic cells offers many potential applications in biomedicine and basic research. The objective of this study was to test whether clones from the same genotype can be used as models to study the genetic influences of behavior. Specifically, several aspects of the behavior of four prepubertal heifers cloned from somatic cells of a 13-year-old Holstein cow along with age-matched control heifers were compared to determine whether juvenile clones from an aged adult behave similarly to their age-matched controls, and whether clones with identical genetic makeup exhibit any behavioral trends. Behavioral observations or behavior challenge tests were conducted to compare the following traits: vocalization, play behavior, movement frequencies, grooming, curiosity, and companion preference, as well as dominance and aggressiveness. From play behavior, movements and vocalization, we observed that these four juvenile clones of an aged genetic donor did not show behavioral indications of aging and were similar to their counterparts of comparable chronological age except that they tended to play less than controls. Behavioral trends were also observed in the clones that indicated that they exhibited higher levels of curiosity, more grooming activities and were more aggressive and dominant than controls. Furthermore, these four clones preferred each other or the donor as companions, which may indicate genetic kin recognition.

Follicular dynamics in water buffalo superovulated in presence or absence of a dominant follicle

The ovaries of 12 buffalo were examined daily by ultrasound beginning at Day 3 of the estrous cycle, followed by superovulation between Days 10 and 13 of the cycle. The buffalo were divided into 2 groups on the basis of the presence (dominant, n = 7) or absence (nondominant, n = 5) of a dominant follicle at the start of superovulation. Daily ultrasonographic observations of the ovaries were recorded on a videotape and were used to assess the progression of both the large (dominant) follicle and the next-to-the-large (subdominant) follicle as well as the numbers of follicles in the small (4 to 6 mm), medium (7 to 10 mm), and large (>10 mm) size categories, before and during the superovulation treatment. A greater number of small size (P < 0.05) follicles was available before the start of the superovulatory treatment in the buffalo superovulated in the absence of a dominant follicle. The turnover of follicles from medium to large size classes also occurred sooner (P < 0.01), and was of higher magnitude (P < 0.01) during treatment in buffalo of the nondominant follicle group. The number of corpora lutea at palpation per rectum was higher (P < 0.05) in buffalo of the nondominant than the dominant group (4.6 +/- 0.6 vs 2.7 +/- 0.5). However, there was no significant difference among the groups in the means of serum progesterone concentration (3.6 +/- 1.3 vs 2.2 +/- 0.6 ng/ml), total number of embryos (2.0 +/- 0.6 vs 1.1 +/- 0.7), transferable embryos (1.6 +/- 0.5 vs 1.0 +/- 0.6) and unfertilized ova recovered (0.4 +/- 0.2 vs 0) on Day 6. It is concluded that in buffalo, the superovulatory response could possibly be improved by ultrasongraphic observation of the status of follicular dominance prior to treatment.