Hot topic: Successful fixed-time insemination within 21 d after first insemination by combining chemical pregnancy diagnosis on d 18 with a rapid resynchronization program.

Cattle that are not pregnant to first fixed-time artificial insemination (TAI) may be resynchronized for a second TAI if they are found nonpregnant at pregnancy diagnosis. The specific interval between first and second TAI ranges from 4 to 8 wk. The selected interval depends on the available method of pregnancy diagnosis and the efficiency of the resynchronization program. The objective of this experiment was to evaluate a pregnancy diagnosis and resynchronization system that achieved a 21-d interval between TAI. This 21-d interval approximates the natural return-to-service interval. It also enables resynchronization to be implemented within the same estrous cycle in which cattle are first inseminated. Holstein heifers were randomly assigned to a 21-d resynchronization program (21d_resynch; n = 40) or a control group in which estrus was observed for the purpose of re-insemination (control; n = 29). The 21d_resynch heifers were diagnosed for pregnancy on d 18 after a TAI (d 0) by using predetermined cut-off values for 2'-5' oligoadenylate synthetase 1 (Oas1) gene expression in leukocytes and plasma progesterone concentration. Heifers that were not pregnant to first TAI had greater expression of Oas1 at the time of PGF(2α) (d -3) than pregnant heifers, but this relationship was reversed on d 18 after TAI: the heifers that were pregnant to first TAI had almost 5-fold greater expression of Oas1 compared with nonpregnant heifers. Nonpregnant heifers in the 21d_resynch group were injected with a luteolytic dose of PGF(2α) on d 19 and were injected with GnRH on d 21 and submitted to TAI. The pregnancy per AI after first insemination was similar for 21d_resynch (50.0%; pregnancy diagnosis on d 18) and control (51.7%; pregnancy diagnosis on d 27). Likewise, no difference was detected in second insemination pregnancy per AI for 21d_resynch (36.8%; nonpregnant heifers TAI on d 21) and control (35.7%; nonpregnant heifers inseminated at return to estrus or after nonpregnant diagnosis on d 27). The interval between first and second insemination was shorter for 21d_resynch compared with control (21.0 ± 0 and 27.5 ± 2.1 d). The conclusion is that a TAI resynchronization can be programmed within 21 d of previous TAI when a d 18 pregnancy test and a rapid resynchronization are used.

Immunofluorescent localization of the proteins of nuclear ribonucleoprotein complexes.

Antibodies were raised in chickens against heterogeneous nuclear RNA (hnRNA)-binding proteins from 30S ribonucleoprotein (RNP) complexes of mouse Taper hepatoma ascites cell nuclei. The antibody preparations were characterized for immunological specificity and purity by double-diffusion gels, binding to specific bands in SDS polyacrylamide gels, and crossed immunoelectrophoresis. Antibodies raised against either whole 30S RNP complexes or purified RNP core proteins had a strong selective affinity for the four 34,000- to 40,000-dalton polypeptides which comprise the major structural proteins of hnRNP. The intracellular distribution of 30S RNP antigens in mouse ascites cells was determined by indirect immunofluorescence microsacopy. In interphase cells immunofluorescent sites were restricted to the nucleus, and nucleoli were free of fluorescence. The chicken anti-mouse-RNP antibodies were also able to react with cells from many different vertebrate species, showing a similar nucleus-restricted localization of the reacting sites. The antibodies also bound chick 30S RNP-proteins and reacted with the nuclei of chick cells. An exception to this was the failure of the antibody to bind to adult chick erythrocytes, suggesting that these major hnRNA binding proteins may be found only in nuclei capable of RNA synthesis.

Short communication: Growth hormone receptor expression in two dairy breeds during the periparturient period.

The growth hormone receptor (GHR) 1A mRNA decreases after calving in the liver of Holstein dairy cows and may coordinate nutrient partitioning. The hypothesis that the decrease in GHR1A mRNA around the time of calving was characteristic of a second dairy breed was tested by examining Guernsey cows in addition to Holstein cows. Holstein and Guernsey cows were housed together and paired by parity and expected calving date. Liver biopsies and blood samples were collected prepartum (d -20 +/- 1) and postpartum on d 3, and d 14 +/- 1. The amounts of GHR1A, GHR1B, GHR1C, and insulin-like growth factor (IGF)1 mRNA were determined by quantitative reverse transcription polymerase chain reaction. Blood concentrations of growth hormone (GH) and IGF1 were measured by RIA. Both breeds underwent a decrease in GHR1A mRNA, a decrease in liver IGF1 mRNA, a decrease in blood IGF1, and an increase in blood GH after calving. The decrease in liver GHR1A and IGF1 mRNA after calving may be an inherent characteristic of dairy breeds that enables nutrient partitioning for greater milk production. Independent genetic selection in 2 dairy breeds seemingly exploited a similar mechanism, reduced GHR1A expression, to decrease blood IGF1 and increase blood GH, a key hormone involved in nutrient partitioning.

Exogenous somatotropin alters IGF axis in porcine endometrium and placenta.

The aim of this study was to examine whether exogenous somatotropin (ST) can alter the insulin-like growth factor (IGF) axis in the porcine epitheliochorial placenta. Crossbred gilts were injected either 6 mg of recombinant porcine ST or vehicle from days 10 to 27 after artificial insemination (term day 116). Control and ST-treated gilts were euthanized on day 28 (8 control/5 treated), day 37 (4 control/6 treated), and day 62 (4 control/6 treated) of gestation. Endometrium and placental tissue samples were collected and subjected to mRNA analyses. In control gilts, somatotropin receptor (STR) and IGF-I mRNA abundance in the endometrium decreased with gestation. Conversely, the amounts of IGF-II mRNA and of IGF binding protein (BP)-2 and -3 mRNA, which were analyzed in endometrium and placental chorion, increased with gestation. The endometrium contained less IGF-II mRNA but more IGFBP-2 and-3 mRNA than the placental chorion. In response to pST treatment, the amounts of endometrial STR and IGF-I mRNA were lower at days 28 and 37, but higher at day 62 of gestation. The content of IGF-II mRNA was higher in the endometrium of pST-treated than control gilts on day 37. The amount of IGFBP-2 mRNA was increased on day 37 in endometrium and placenta of pST-treated gilts, whereas no changes in IGFBP-3 mRNA were observed. The IGF-II/IGFBP-2 ratio was higher in the placenta in response to pST on day 28 of gestation. Results show that pST treatment of pregnant gilts during early gestation alters IGF axis in maternal and fetal placental tissues and suggest pST may exert an effect on fetal growth by altering the relative amount of IGFBPs and IGFs at the fetal-maternal interface.

Identification of Sp1 as the transcription factor for the alternative promoter P2 of the bovine growth hormone receptor gene.

Growth hormone receptor (GHR) mRNA variants that differ in the 5'-untranslated regions (5'-UTR) have been isolated in various species. These 5'-UTR variants are generated from the use of alternative promoters and/or alternative splicing. The 5'-UTR 1B is one of the GHR 5'-UTR variants isolated in the bovine but its homologues are also present in other species. The 5'-UTR 1B is a predominant GHR 5'-UTR expressed in many tissues. In the present study, we screened a bovine genomic library and isolated a 1.7 kb bovine GHR genomic sequence including exon 1B and its 5' flanking region from which the GHR 5'-UTR 1B is generated. Using primer extension, two major transcription start sites were mapped in the bovine exon 1B. Transient transfection analysis of the 5' flanking region of exon 1B confirmed its promoter activity (termed P2) in both Hep G2 and BHK-21 cells. Furthermore, analysis of deletion promoter-reporter constructs found that the basal activity of P2 resided in the proximal region of P2. DNase I footprinting analysis and electromobility shift assay (EMSA) identified the ubiquitous transcription factor Sp1 as the binding protein to a GC box-containing DNA element within the proximal P2. Deletion of the GC box greatly reduced the activity of P2 in cell lines. The GC box-containing site also appeared to bind Sp1 in the nuclear extracts from diverse bovine tissues. This suggests that interactions of Sp1 with the GC box-containing element in the proximal region of P2 may be part of the mechanism for the expression of the bovine GHR 5'-UTR 1B in diverse tissues.

Expression and location of IGF binding proteins-2, -4, and -5 in developing fetal tissues.

Insulin-like growth factors are associated with myogenesis in vivo, and their actions are mediated by IGF binding proteins (IGFBP). Sites of IGFBP production and their location during early development are not clear. The objective of this research was to examine the developmental expression and location of IGFBP-2, -4, and -5 mRNA and peptides in developing porcine skeletal muscle and liver. Pregnant pigs were euthanatized at various times postconception (pc). Developmental expression of IGFBP was evaluated using total RNA extracted from skeletal muscle and liver of 30-, 44-, 59-, 68-, 75-, 89-, and 109-d pc fetuses and from adult and neonatal pigs. Localization of IGFBP-2, -4, and -5 mRNA and peptides was examined by in situ hybridization and immunocytochemistry of muscle samples from contralateral pelvic limbs of each pig. Overall muscle IGFBP gene expression decreased (P < .05) with increasing age. Moreover, expression of liver IGFBP-2 and -5, but not of IGFBP-4, was greater (P < .05) during prenatal than during postnatal periods. The majority of immunoreactive IGFBP was located in developing muscle cells, with little localized to connective tissue, except at later stages of development. These data show that IGFBP-2, -4, and -5 expression is time- and tissue-dependent in fetal liver and muscle.

Developmental expression and location of IGF-I and IGF-II mRNA and protein in skeletal muscle.

To investigate the role of IGF in muscle development in vivo, developmental expression and location of IGF-I and -II protein and mRNA were examined in fetal, postnatal, and adult skeletal muscle. Muscle tissue was collected from 30-, 44-, 59-, 68-, 75-, 89-, and 109-d porcine fetuses, 21-d neonatal pigs, and 6-mo-old (adult) pigs. Relative amounts of IGF-II mRNA peaked (P < .05) in 59-d fetal muscle and decreased thereafter. Inversely, muscle IGF-I expression increased (P < .05) to maximal levels around birth. For in situ hybridization, frozen muscle tissue sections (10 microm) were hybridized with a hydrolyzed form of the same riboprobes or incubated with polyclonal or monoclonal antibodies to IGF-I or -II, respectively. The majority of IGF-I and IGF-II mRNA was localized to developing muscle fibers, whereas little signal was found in the surrounding connective tissues. Immunofluorescent localization of IGF-I and -II confirmed that muscle IGF are present in developing muscle fibers. Collectively, these data show that IGF-I and -II are expressed and produced primarily in muscle cells within developing muscle tissue and support the hypothesis that IGF-I and -II modulate fetal muscle development.

Evidence for three adult fast myosin heavy chain isoforms in type II skeletal muscle fibers in pigs.

Three main fiber types (one slow [type I] and two fast [type IIA and IIB] can be distinguished using conventional actomyosin ATPase (AM-ATPase) histochemistry after acidic pretreatment in mature pig skeletal muscle. We report the isolation, characterization, and identification of four adult 3'-untranslated regions corresponding to types I, IIA, IIB, and IIX myosin heavy chains (MyHC) from a cDNA library. Identification of different type II clones was based on sequence homology, in situ hybridizations (ISH), AM-ATPase histochemistry, and immunocytochemistry. Enzyme histochemistry, immunocytochemistry, and ISH were performed on serial transverse sections of longissimus and red portion of semitendinosus muscle. Results showed that all three fast MyHC transcripts were expressed in the longissimus, whereas only type IIA and IIX transcripts were present in deep red semitendinosus muscle. Type I and IIA fibers contained mostly type I and IIA transcripts, respectively, whereas type IIB fibers contained a heterogeneous population of transcripts. In longissimus muscle, 18, 31, and 51% of conventional IIB fibers were pure IIX, hybrid IIX/IIB, and pure IIB fibers, respectively. Conversely, conventional IIB fibers were actually IIX in deep red semitendinosus muscle. Expression of the three fast adult MyHC isoforms in longissimus was spatially regulated around the typical islets of type I fibers encountered in pig skeletal muscle. Thus, IIA fibers were contiguous to type I fibers, pure IIX fibers were in the direct vicinity of type I and IIA fibers, and hybrid IIX/IIB fibers were located mostly within primary fascicles between the islets of type I fibers; however, pure IIB fibers were located mainly at the periphery of the rosettes near the edges of primary fascicles. In light of the present study, conventional IIB fibers, as defined with AM-ATPase staining, are a heterogeneous population that should be split into pure IIX, hybrid IIX/ IIB, and pure IIB fibers for a more accurate fiber typing.

Quantification of myosin heavy chain isoform in porcine muscle using an enzyme-linked immunosorbent assay.

The objective of this study was to develop an indirect enzyme-linked immunosorbent assay (ELISA) to quantify the relative abundance of the myosin heavy chain (MyHC) isoforms in porcine muscle. Longissimus muscle samples were taken from halothane positive (HAL+) and negative (HAL-) pigs and subjected to ELISA using newly generated and commercially available myosin monclonal antibodies (mAbs). Muscle of HAL+ pigs possessed less type I (P <0.01) and IIA (P<0.1), and more type IIB MyHC (P <0.01) than muscle of HAL- pigs. Abundance of IIX MyHC content was negatively correlated (P < 0.0001) to the amount of IIB MyHC in porcine muscle. These data show indirect ELISA can be used to detect genotype differences in muscle MyHC content, and it provides a rapid, sensitive method for determining muscle fiber type in porcine skeletal muscle. Furthermore, these data suggest that the proportion of glycolytic muscle fibers increases at the expense of oxidative fibers.

Measurement of interferon-tau (IFN-tau) stimulated gene expression in blood leukocytes for pregnancy diagnosis within 18-20d after insemination in dairy cattle.

The objective was to diagnose pregnancy within 18d after insemination by measuring interferon-tau (IFN-tau)-stimulated genes (ISG) expression in circulatory leukocytes. Based on microarray results, three genes were selected [2'-5' oligoadenylate synthetase 1(Oas1), myxovirus resistance gene 2 (Mx2), and interferon-stimulated gene 15kDa protein (Isg15)] because they were known to be interferon-stimulated genes (ISG) and were also differentially expressed in the samples. The respective genes were assayed by using real time reverse transcriptase polymerase chain reaction (RTPCR). In the first experiment, RNA was isolated from leukocytes of pregnant (n=5) and non-pregnant (n=15) dairy cows on each of d 14, 16, 18, and 20 after insemination. The ISG expression (Mx2 and Isg15) was greater in pregnant compared with non-pregnant cows on d 18 and 20. In the second experiment, we attempted to define the shortest interval to pregnancy detection by measuring ISG on d 17 (Exp. 2A) or d 18 (Exp. 2B). For Exp. 2A, blood was collected from pregnant (n=16) and non-pregnant (n=16) cows on d 17 after insemination. On d 17, pregnant cows had greater Mx2 and Oas1 but Receiver Operator Characteristic (ROC) curves showed that the increase was too small to develop a suitable cut-off for a reliable pregnancy test. For Exp. 2B, blood samples were collected from pregnant (n=21) and non-pregnant (n=21) cows on d 18 after insemination. For both Mx2 and Oas1, primiparous pregnant cows had greater ISG expression than primiparous non-pregnant cows on d 18. For multiparous cows, however, pregnant and non-pregnant cows were similar for ISG expression on d 18. The possibility of correcting for pre-insemination ISG expression was examined in a final series of experiments. Blood samples were collected from cows (n=54) and heifers (n=24) during the luteal phase preceding insemination. A second sample was collected from the same cows [pregnant (n=13) and non-pregnant (n=41)] and heifers [pregnant (n=17) and non-pregnant (n=7)] 18d after insemination. The ratio of the second sample (after insemination) to the first sample (before insemination) minimally increased the sensitivity of the ISG test for pregnancy detection. There was a large increase in ISG expression on d 18 of pregnancy in heifers (approximately 1 year of age) that could be measured for a reliable pregnancy test. The conclusion from the studies is that a reliable ISG-based method for pregnancy detection could be applied as early as d 18 but only in heifers. Older cows have a lesser response that reduces the sensitivity of the ISG test on or before d 18.

Isolation and characterization of a novel promoter for the bovine growth hormone receptor gene.

The use of alternative promoters represents an important mechanism for the regulation of growth hormone receptor (GHR) gene expression. Two promoters have been isolated previously for the GHR gene: the P1 promoter that drives liver-specific expression, and the P2 promoter that drives ubiquitous expression. In the present study, we isolated a third GHR promoter termed P3. The P3 promoter was GC-rich and TATA-less. The P3 promoter was able to drive the expression of a luciferase reporter gene in cell lines Hep G2, PLC/PRF/5, and BHK-21. In vivo, the P3 promoter initiated transcription from two major sites in exon 1C of the GHR gene in many tissues. In the adult bovine liver, the P3-transcribed GHR mRNA represented only 10% of the total GHR mRNA pool. In non-hepatic tissues such as kidney, skeletal muscle, mammary gland, and uterus, P3-transcribed GHR mRNA represented 30-40% of the total GHR mRNA pool. Within the bovine GHR gene, the P3 promoter was located immediately downstream from the P2 promoter. In transfected cells, the P2 promoter served as an enhancer for the P3 promoter. Existence and co-regulation of two ubiquitous promoters may be a mechanism for achieving a high level of expression of the GHR gene in multiple tissues.

Expression of somatotropin receptor messenger ribonucleic acid in bovine tissues.

The somatotropin receptor mRNA is controlled by at least two different gene promoters that generate two variants with different exon 1 sequences (1A and 1B). The location of 1A and 1B somatotropin receptor mRNA within cattle tissues and, hence, the tissue specificity of the 1A and 1B promoters are unknown. In addition, the cDNA sequence of the 1B somatotropin receptor has not been determined. Our objective, therefore, was to sequence a cDNA for the 1B somatotropin receptor and to analyze bovine tissues for expression of 1A and 1B somatotropin receptor mRNA. Twenty adult tissues and six fetal tissues were collected at slaughter from each of four cows and two fetuses. Messenger RNA was analyzed using ribonuclease protection assays. The adult liver expressed both 1A and 1B mRNA. All other adult tissues expressed 1B mRNA but not 1A mRNA. The greatest amount of 1B mRNA was detected in liver and adipose (abdominal and subcutaneous) tissues. Other tissues had approximately one-half to one-tenth of the amount of 1B mRNA in the liver or adipose tissue. Fetal tissues (including fetal liver) expressed 1B mRNA and not 1A mRNA. Based on cDNA sequencing, the protein encoded by the 1A and 1B mRNA was nearly identical. We concluded that 1A somatotropin receptor mRNA is specific to adult bovine liver. Other adult and fetal bovine tissues expressed 1B somatotropin receptor mRNA with a predicted protein sequence that was similar to the 1A somatotropin receptor.

Myofiber injury and regeneration in a canine homologue of Duchenne muscular dystrophy.

OBJECTIVE: To test the hypothesis that differential skeletal muscle involvement, previously observed in dogs with a homologue of Duchenne muscular dystrophy, correlates with the histochemical markers of myofiber injury and regeneration. DESIGN: Evidence of injury (cellular penetration by Evans blue dye, immunoglobulin G expression, hematoxylin and eosin staining of necrotic figures), myofiber regeneration (fetal myosin heavy chain isoform expression), and morphologic indices in the cranial sartorius (CS), long digital extensor, and vastus lateralis muscles were examined in five dogs with dystrophy and five normal dogs. RESULTS: Only the CS muscle, at 1 mo, demonstrated significant differences in injury when compared with age-matched controls. By 6 mo, the long digital extensor and vastus lateralis also suffered greater than normal injury. Only the dystrophic CS tissue expressed a notable increase in mean myofiber diameter when compared with other muscles at 6 mo. Normal CS muscles revealed a distinct population of small myofibers at this age. CONCLUSION: The CS seems unique in its selective pathologic involvement. These differences may contribute to the marked regenerative response of this muscle in the dystrophic state. An improved understanding of mechanisms by which some dystrophin-deficient canine muscles remain spared from injury may provide clues to investigate and prevent the degenerative processes in humans.