Perinatal Physiology in Cloned And Normal Calves: Hematologic And Biochemical Profiles

Evaluation of postnatal growth, hematology, telomere length and semen attributes of multiple clones and re-clone of superior buffalo breeding bulls

The present study comprehensively evaluates the postnatal growth, hematology, telomere length, and semen attributes of multiple clones and re-clone derived from superior buffalo breeding bulls. To the best of our knowledge, we successfully produced multiple clones and a re-clone of an earlier cloned buffalo bull from an embryo developed from an adult bull's skin-derived cell for the first time. The cloned bulls' growth, blood hematology, plasma biochemistry, and telomere length were all shown to be normal at various stages of development. The bulls were used for semen production after being screened for testicular growth and training. Semen characteristics such as volume, concentration, and initial motility of fresh sperm as well as motility and kinetics characteristics such as straightness (STR), average lateral head displacement (ALH), and beat cross frequency (BCF) of frozen-thawed sperms of the cloned bulls were found to be similar to those of non-cloned bulls, including the donor bulls. Additionally, it was found that cloned bulls' functional sperm attributes, including acrosome intactness, mitochondrial membrane potential, and superoxide anion status, were comparable to those of non-cloned bulls. These characteristics are necessary for sperm to pass through the female reproductive system, penetrate the oocyte, and efficiently fertilize. Finally, this study adds to our understanding of the postnatal development, hematology, telomere length, and sperm characteristics of superior buffalo breeding bulls that have been cloned and re-cloned. The findings provide the groundwork for improving cloning practices, refining reproductive procedures, and optimizing the use of cloned genetic material in animal breeding and conservation.

Components of the insulin-like growth factor system in in vivo - and in vitro-derived fetuses of cattle, and the association with growth and development

This experiment was designed to study mechanisms affecting growth of in vivo-derived (IVD) and in vitro-produced (IVP) fetuses of cattle. Day-7 IVD or IVP cattle blastocysts were transferred to recipients, with pregnant females being slaughtered on Days 90 or 180 of gestation or allowed to undergo parturition. Uteri and contents were dissected and physically measured, and maternal and fetal plasma and amniotic and allantoic fluids were collected for IGF-1 and IGF-2 determinations, and IGFBP profile characterization. Transcripts for IGF-1 and IGF-2 mRNA in placental and fetal tissues, and IGF-1r and IGF-2r in placentomes were determined. There was a greater fetal weight in the IVP group, which was associated with greater IGF-1 and IGF-2 concentrations in maternal circulation, and changes in IGFBP profiles within fetal fluids. Day-90 IVP-derived fetuses were longer, had greater organ weights, larger placentomes, less placentome IGF-2r mRNA transcript, and greater maternal IGF-1 and IGF-2 concentrations than controls. On Day 180 and at parturition tissues from IVP-derived fetuses/calves were from larger uteri, with larger placentomes/fetal membranes, fetuses/calves weighed more, had greater fetal hepatic IGF-2 mRNA transcript, had less fetal plasma IGF-1 and greater allantoic IGF-2 concentrations, greater and lesser IGFBP activities in the allantoic and amniotic fluids, respectively, and greater glucose and fructose accumulation in fetal fluids. Components of the IGF system were differentially regulated not only according to the gestation period (Days 90 or 180) and fluid type (maternal or fetal plasma, amniotic or allantoic fluids), but also based on conceptus origin (IVP or IVD) in cattle.

Venous blood gas parameters in healthy Mediterranean buffalo calves in the first 72 hours of life

In the first hours after calving the neonate radically modifies its anatomy and physiology to adapt to extrauterine life. These modifications, however, make the calf prone to respiratory and metabolic dysfunction. Thus, stillbirth, defined as the death of the neonate within 48 h after birth, represents a relevant issue for buffalo farming. Of the clinical procedures, the blood gas analysis of venous samples provides useful information regarding the acid-base status of the neonate, allowing the optimal management of potential illness calves. However, the blood gas parameters have never been studied in the buffalo calf in the first 72 h of life. Thus, this study aimed to report blood gas parameters at calving and 1, 12, 24, and 72 h after birth in healthy buffalo neonates born after normal parturition. The study involved 20 healthy buffalo calves, born from normal pregnancy and parturition. The parturition and the first hours after were monitored by closed-circuit television cameras, and within 1 min after calving the buffalo neonate received a clinical evaluation (APGAR, temperature), venous blood sampling for blood gas (pH, partial pressure carbon dioxide - pCO₂, partial pressure oxygen - pO₂, base excess, bicarbonate concentration, oxygen saturation, total carbon dioxide - tCO₂, and lactate), and glycemia analysis. The same evaluations were performed after 1, 12, 24, and 72 h. The present study showed a moderate mixed acidosis at calving, similar to that reported in the bovine neonate, likely due to the high venous blood pCO₂ and lactate. This acidemia resolved spontaneously within 12 h as a reduction of pCO₂ (P ≤ 0.05). Lactate reduced significantly (P ≤ 0.05) only at 72 h, similarly to the trend reported previously for the bovine calf. Blood lactate concentration was correlated with glycemia at calving and 1 h (r = 0.677, P = 0.014), and with stage 2 duration (r = 0.647, P = 0.006). These findings support a possible mechanism of glucose generation induced by catecholamines coupled to anaerobic metabolism soon after calving. After calving, all the blood gas parameters changed rapidly reaching values comparable with those reported in the literature for older buffalo calves from 72 h after calving. No correlations were found between APGAR score and venous blood gas parameters, likely due to the inclusion criteria that selected only health buffalo calves born after normal parturition. The findings suggested that the venous blood gas analysis could be considered supportive rather than an alternative to the clinical evaluation of the buffalo calf.

Morphometric developmental pattern of bovine handmade cloned concepti in late pregnancy

Cloning procedures often interfere with conceptus growth and life ex utero, in a set of symptoms known as abnormal offspring syndrome (AOS). The aim of the present study was to compare the developmental pattern of in vivo-derived (IVD), IVF-derived and handmade cloning-derived (NT-HMC) Day 225 bovine concepti using established procedures. Pregnancy diagnosis was performed on Day 30 following blastocyst transfer on Day 7. Conceptus morphometry was assessed by ultrasonography on Day 51, and on Day 225 pregnant cows were killed for morphological examination of concepti. Pregnancy outcome was similar between groups, with greater pregnancy losses in the first trimester (70.6%) and smaller fetuses on Day 51 in the NT-HMC group than in the IVD (14.3%) and IVF (20.0%) groups. However, NT-HMC-derived concepti were twofold larger on Day 225 of gestation than controls. A higher frequency (63.5%) of placentomes larger than the largest in the IVD group was observed in the NT-HMC group, which may be relevant to placental function. Conceptus traits in the IVF group were similar to the IVD controls, with only slight changes in placentome types. Morphological changes in cloned concepti likely affected placental function and metabolism, disrupting the placental constraining mechanism on fetal growth in mid- to late pregnancy.

Altered DNA methylation associated with an abnormal liver phenotype in a cattle model with a high incidence of perinatal pathologies

Cloning enables the generation of both clinically normal and pathological individuals from the same donor cells, and may therefore be a DNA sequence-independent driver of phenotypic variability. We took advantage of cattle clones with identical genotypes but different developmental abilities to investigate the role of epigenetic factors in perinatal mortality, a complex trait with increasing prevalence in dairy cattle. We studied livers from pathological clones dying during the perinatal period, clinically normal adult clones with the same genotypes as perinatal clones and conventional age-matched controls. The livers from deceased perinatal clones displayed histological lesions, modifications to quantitative histomorphometric and metabolic parameters such as glycogen storage and fatty acid composition, and an absence of birth-induced maturation. In a genome-wide epigenetic analysis, we identified DNA methylation patterns underlying these phenotypic alterations and targeting genes relevant to liver metabolism, including the type 2 diabetes gene TCF7L2. The adult clones were devoid of major phenotypic and epigenetic abnormalities in the liver, ruling out the effects of genotype on the phenotype observed. These results thus provide the first demonstration of a genome-wide association between DNA methylation and perinatal mortality in cattle, and highlight epigenetics as a driving force for phenotypic variability in farmed animals.

Effect of calf death loss on cloned cattle herd derived from somatic cell nuclear transfer: clones with congenital defects would be removed by the death loss

To increase public understanding on cloned cattle derived from somatic cell nuclear transfer (SCNT), the present review describes the effect of calf death loss on an SCNT cattle herd. The incidence of death loss in SCNT cattle surviving more than 200 days reached the same level as that in conventionally bred cattle. This process could be considered as removal of SCNT cattle with congenital defects caused by calf death loss. As a result of comparative studies of SCNT cattle and conventionally bred cattle, the substantial equivalences in animal health status, milk and meat productive performance have been confirmed. Both sexes of SCNT cattle surviving to adulthood were fertile and their reproductive performance, including efficiency of progeny production, was the same as that in conventionally bred cattle. The presence of substantial equivalence between their progeny and conventionally bred cattle also existed. Despite these scientific findings, the commercial use of food products derived from SCNT cattle and their progeny has not been allowed by governments for reasons including the lack of public acceptance of these products and the low efficiency of animal SCNT. To overcome this situation, communication of the low risk of SCNT technology and research to improve SCNT efficiency are required.

Neonatal morbidity and mortality of 31 calves derived from somatic cloning

BACKGROUND

The neonatal period is associated with high morbidity and mortality in cloned calves.

OBJECTIVE

To describe morbidity and mortality in cloned calves from birth to 2 years of age.

ANIMALS

Thirty-one somatic cell-derived Holstein calves delivered at a veterinary teaching hospital.

METHODS

Medical files were retrospectively analyzed.

RESULTS

Four calves were stillborn. Five calves born alive had physical congenital defects. Twenty-three calves had an enlarged umbilical cord. Laboratory abnormalities included acidemia, respiratory acidosis, hyperlactatemia, anemia, stress leukogram, decreased total protein, albumin and globulins, and increased creatinine. Twenty-five calves survived the 1st hour of life. Among them, 11 stood without assistance within 6 hours of birth, 10 calves took longer than 6 hours to stand, and 4 never stood. Twenty-two calves suffered from anorexia. Twelve calves had complications arising from umbilical cord infections. Three calves developed idiopathic hyperthermia (>40°C). Eight calves suffered from gastrointestinal problems, including ruminal distension, abomasal ulcers, neonatal enteritis, intussusception, and abomasal displacement. Mortality between birth and 3 weeks of age was 32% (10/31). Causes of death and reasons for euthanasia included stillbirths, respiratory failure, and limb deformities. Mortality between 3 weeks and 2 years of age was 19% (4/21), with deaths in this group attributed to generalized peritonitis and complications arising from umbilical infections. Overall, mortality rate within 2 years of age was 14/31 (45%).

CONCLUSION AND CLINICAL IMPORTANCE

Respiratory problems, limb deformities, and umbilical infections were the most common causes of morbidity and mortality in these cloned calves.

Body growth, hematological profile, and clinical biochemistry of heifer calves sired by a bull or its clone

The aim of this paper was to compare body growth, hematological profile development, and clinical biochemistry in the female progeny of a sire with the female progeny of its clone. Sixteen Friesian female calves, 9 daughters from a tested bull (BULL) and 7 from its somatic cell nuclear transfer clone (CLONE) were monitored from birth to 60 wk of life. Body weight (BW), wither height (WH), hip height (HH), body length (BL), and hearth girth (HG) were measured at birth and 4, 8, 12, 16, 20, 24, 36, and 50 wk. Blood samples were taken from jugular vein at 12 to 48 h from birth and 1, 2, 3, 4, 8, 12, 16, 20, 24, and 36 wks of age, to be analyzed for hematological, serum protein, and metabolic profiles. At the same time, rectal temperature (RT) was recorded. Age at puberty was assessed on surviving heifers by measuring weekly plasma progesterone levels. Data were evaluated using a mixed model, taking into account the repeated measures in time on the calf. For each variable, different covariance structures were tested, choosing the best according to the Akaike's Information Criteria. Significant was set at P < 0.05, and a trend was considered for P < 0.10. At 24 wk of age, WH was lower in CLONE daughters than BULL daughters. Around 20 wk of age, there was a trend for lower BW in CLONE daughters than BULL daughters, confirmed from differences in HG. There was no difference in RT due to sire effect. Blood glucose concentration decreased in both groups during the first 4 wk of life; at birth, only a trend for higher blood glucose in CLONE daughters was recorded, whereas an opposite trend was observed for plasma creatinine. Total leukocyte count did not differ between progenies. Circulating lymphocytes tended to be lower in CLONE than BULL daughters. The neutrophil: lymphocyte ratio tended to be higher in CLONE than BULL calves. No difference was demonstrated for erythrocyte features, whereas mean platelet volume tended to be lower in CLONE than BULL progeny. From these results, there were no differences between progenies from BULL and its clone that suggest welfare problems in the first 6 mo of life.

Delivery of cloned offspring: experience in Zebu cattle (Bos indicus)

The production of a healthy cloned calf is dependent on a multitude of successful steps, including reprogramming mediated by the oocyte, the development of a functional placenta, adequate maternal–fetal interaction, the establishment of a physiological metabolic setting and the formation of a complete set of well-differentiated cells that will eventually result in well-characterised and fully competent tissues and organs. Although the efficiency of nuclear transfer has improved significantly since the first report of a somatic cell nuclear transfer-derived animal, there are many descriptions of anomalies concerning cloned calves leading to high perinatal morbidity and mortality. The present article discusses some our experience regarding perinatal and neonatal procedures for cloned Zebu cattle (B. indicus) that has led to improved survival rates in Nellore cloned calves following the application of such ‘labour-intensive technology’.

Angiogenesis in day-30 bovine pregnancies derived from nuclear transfer

Impaired placental angiogenesis during early pregnancy may result in placental defects that adversely affect development of nuclear-transfer (NT) embryos later in pregnancy. These experiments were designed to quantify and compare development of placental microvasculature and expression of genes associated with angiogenesis, including members of the VEGF and angiopoietin (Ang) families, in maternal and embryonic placental tissues of day 30 bovine concepti derived from NT or in vitro fertilization (IVF) followed by in vivo development to the blastocyst stage in the sheep oviduct. Microvascular volume density (MVD) within the caruncular tissues, as determined using Periodic Acid-Schiff's staining as well as immunohistochemical staining for von Willebrand's factor, was not different between NT- and IVF- derived pregnancies. Expression of genes implicated in angiogenic mechanisms, including VEGF-A and -C, placental growth factor (PlGF), VEGF receptors (Flt-1, Flk-1, and Flt-4), angiopoietin-1 (Ang1), Ang2, Tie1, Tie2, and hypoxia-inducible factor (HIF), were determined. In chorio-allantoic membranes, levels of PlGF transcripts were significantly lower in NT- than IVF-derived tissues (p<0.05), whereas HIF-1alpha transcription in chorio-allantoic membranes of cloned concepti was higher at p<0.10. Caruncular expression of HIF-1alpha and Ang1 also was increased in NT-derived pregnancies at p <or= 0.10. Immunohistochemical staining of caruncular tissues for VEGF-A and the Flt-1 receptor revealed few differences in protein expression between NT- and IVF-derived pregnancies. These results indicate that expression of most angiogenic factors at day 30 of gestation is not altered as a result of the NT procedure; however, given reports of impaired placental vascular development in NT-derived bovine embryos, perturbations in angiogenesis may occur subsequently during early placental development and throughout gestation. Elevated expression of the HIF-1alpha gene in maternal and chorio-allantoic tissues of cloned concepti may suggest a generalized hypoxic condition in early placental tissues of NT-derived concepti, which could adversely affect subsequent development of the placenta.