Suitability of cross-bred cows for organic farms based on cross-breeding effects on production and functional traits.

Data from 113 Dutch organic farms were analysed to determine the effect of cross-breeding on production and functional traits. In total, data on 33 788 lactations between January 2003 and February 2009 from 15 015 cows were available. Holstein-Friesian pure-bred cows produced most kg of milk in 305 days, but with the lowest percentages of fat and protein of all pure-bred cows in the data set. Cross-breeding Holstein dairy cows with other breeds (Brown Swiss, Dutch Friesian, Groningen White Headed, Jersey, Meuse Rhine Yssel, Montbéliarde or Fleckvieh) decreased milk production, but improved fertility and udder health in most cross-bred animals. In most breeds, heterosis had a significant effect (P < 0.05) on milk (kg in 305 days), fat and protein-corrected milk production (kg in 305 days) and calving interval (CI) in the favourable direction (i.e. more milk, shorter CI), but unfavourably for somatic cell count (higher cell count). Recombination was unfavourable for the milk production traits, but favourable for the functional traits (fertility and udder health). Farm characteristics, like soil type or housing system, affected the regression coefficients on breed components significantly. The effect of the Holstein breed on milk yield was twice as large in cubicle housing as in other housing systems. Jerseys had a negative effect on fertility only on farms on sandy soils. Hence, breed effects differ across farming systems in the organic farming and farmers can use such information to dovetail their farming system with the type of cow they use.

Genotype by environment interaction for milk production traits between organic and conventional dairy cattle production in The Netherlands.

Estimates of genetic parameters for organic dairy farming have not been published previously, and neither is information available on the magnitude of genotype by environment interaction (GxE) between organic and conventional farming. However, organic farming is growing worldwide and basic information about genetic parameters is needed for future breeding strategies for organic dairy farming. The goal of this study was to estimate heritabilities of milk production traits under organic farming conditions and to estimate the magnitude of GxE between organic and conventional dairy farming. For this purpose, production records of first-parity Holstein heifers were used. Heritabilities of milk, fat and protein yield, and somatic cell score (SCS) were higher under organic farming conditions. For percentages of fat and protein, heritabilities of organic and conventional production were very similar. Genetic correlations between preorganic and organic, and organic and conventional milk production were 0.79 and 0.80, respectively. For fat yield, these correlations were 0.86 and 0.88, and for protein yield, these were 0.78 and 0.71, respectively. Our findings indicate that moderate GxE was present for yield traits. For percentage of fat and protein and SCS, genetic correlations between organic and conventional and preorganic production were close to unity, indicating that there was no GxE for these traits.

Culture of bovine embryos in buffalo rat liver cell-conditioned media or with leukemia inhibitory factor.

Experiments were designed to study development of bovine embryos in TCM-199 medium conditioned by preculture with buffalo rat liver (BRL) cells. Conditioned media were harvested after BRL cells were cultured until confluency (CON), or for an additional 2 d with the same cells but new medium (CON-N) or the same medium (CON-S). Glucose in TCM-199 was depleted by BRL cells to different concentrations depending on coculture procedures: CON = 3.94 mM, CON-N = 1.67 mM, and CON-S = 1.11 mM glucose. In Exp. 1, development of bovine zygotes in CON-S resulted in fewer blastocysts than development in CON (10 vs 28%, P < .05); CON-N was not different from CON (26% blastocysts). Experiment 2 examined effects of moving embryos to a fresh drop of different or identical conditioned medium after culture for 3 d. Initial culture in CON-N and final culture in CON resulted in a greater (P < .01) number of blastocysts compared with the control of CON followed by CON (32 vs 19% blastocysts). This was not entirely due to changing from low to high glucose because adding glucose to CON-N after 3 d yielded only 18% blastocysts. To test the hypothesis that beneficial effects of BRL cell-conditioned media may be due to secretion of leukemia inhibiting factor (LIF), LIF was added to B2, a more appropriate medium than Medium-199 for culturing bovine embryos without conditioning or coculture with BRL cells. In the absence of serum, the percentage of blastocysts per cleaved embryo (17 to 28%) was not improved with LIF; however, the mean number of cells per blastocyst was higher (P < .05) in treatments with LIF (65 to 74 cells) than without LIF (47 cells). In B2 medium + 10% fetal calf serum, LIF was of no benefit; development to blastocysts was good with or without LIF (43% of cleaved).

The visual cortico-striato-nigral pathway in the rat.

The organization of the visual cortico-striato-nigral pathway in the rat has been investigated in two sets of experiments using anterograde autoradiographic tracing techniques. First, in one group of animals, injections of tritiated amino acids were placed throughout the visual cortex to demonstrate the visual corticostriatal pathway. The results indicate that visual corticostriatal fibres terminate in a distinctive clustered pattern throughout the entire length of the ipsilateral dorsomedial striatum. The projection shows a longitudinal topographic organization with cortical loci projecting onto narrow longitudinal regions of the dorsomedial striatum. In addition to the ipsilateral projection, a substantially smaller contralateral visual corticostriatal projection was also demonstrated. In the second set of experiments, the visual corticorecipient region of the striatum demonstrated in the first set of experiments was injected with tritiated amino acids to demonstrate the "visual" striatonigral projection. The results indicate that striatonigral fibres from the dorsomedial striatum project throughout the rostrocaudal extent of the ventral region of the pars reticulata. As with the visual corticostriatal pathway, the projection shows a longitudinal topographic organization with striatal loci projecting onto longitudinal regions of the ventral pars reticulata; the most rostral regions of the dorsal striatum project to the most medial regions of the ventral pars reticulata and, likewise, successively more caudal regions of the dorsal striatum project to successively more lateral regions of the ventral pars reticulata. In addition to the main projection to the ventral pars reticulata, a second smaller component of the striatonigral pathway was traced to adjacent regions of the dorsal pars reticulata and ventral pars compacta. These findings provide evidence of a visual cortico-striato-nigral pathway to both the pars reticulata and pars compacta in the rat. It is suggested that the major projection onto the ventral pars reticulata may provide an input onto nigrotectal neurons and thereby complete an indirect visual corticotectal connection mediated via links in the basal ganglia.

Cytoarchitecture, fiber connections, and some histochemical aspects of the interpeduncular nucleus in the rat.

The organization of afferent and efferent connections of the interpeduncular nucleus (IP) has been examined in correlation with its subnuclear parcellation by using anterograde and retrograde tracing techniques. Based on Nissl, myelin, and acetylcholinesterase staining five paired and three unpaired IP subnuclei are distinguished. The unpaired division includes the rostral subnucleus (IP-R), the apical subnucleus (IP-A), and the central subnucleus (IP-C). The subnuclei represented bilaterally are the paramedian dorsal medial (IP-DM) and intermediate subnuclei (IP-I) and the laterally placed rostral lateral (IP-RL), dorsal lateral (IP-DL), and lateral subnuclei (IP-L). Immunohistochemical techniques showed cell bodies and fibers and terminals immunoreactive for substance P, leu-enkephalin, met-enkephalin, or serotonin to be differentially distributed over the different IP subnuclei. Substance P-positive perikarya were found in IP-R, enkephalin neurons in IP-R, IP-A, and the caudodorsal part of IP-C, and serotonin-containing cell bodies in IP-A and the caudal part of IP-L. Efferent IP projections were studied both by injecting tritiated leucine in IP and by injecting HRP or WGA-HRP in the presumed termination areas. The results indicate that the major outflow of IP is directed caudal-ward to the median and dorsal raphe nuclei and the caudal part of the central gray substance, i.e., the dorsal tegmental region. The projection appears to terminate mainly in the raphe nuclei, around the ventral and dorsal tegmental nuclei of Gudden, and in the dorsolateral tegmental nucleus. The descending projection to the dorsal tegmental region originates in virtually all IP subnuclei, but the main contribution comes from IP-R and the lateral subnuclei IP-RL, IP-DL, and IP-L. Sparser projections to the dorsal tegmental region originate in IP-C and IP-I, whereas the contribution of IP-A is only minimal. The projections from IP-R are mainly ipsilateral and those from IP-DM are mainly contralateral. IP fibers to the median and dorsal raphe nuclei originate predominantly in IP-R and IP-DM, and to a lesser extent in IP-C, IP-I, IP-RL, and IP-DL. A much smaller contingent of IP fibers ascends to diencephalic and telencephalic regions. A relatively minor projection, stemming from IP-RL and IP-DL, reaches the lateral part of the mediodorsal nucleus, the nucleus gelatinosus, and some midline thalamic nuclei. These IP fibers follow either the habenulo-interpeduncular pathway or the mammillothalamic tract.(ABSTRACT TRUNCATED AT 400 WORDS)

Light microscopic evidence of striatal input to intrapallidal neurons of cholinergic cell group Ch4 in the rat: a study employing the anterograde tracer Phaseolus vulgaris leucoagglutinin (PHA-L).

Injections of the anterograde tracer Phaseolus vulgaris leucoagglutinin (PHA-L) were placed in various striatal loci in the rat. Within the globus pallidus, PHA-L-filled striatofugal axons were seen to approach cholinergic neurons, identified with either acetylcholinesterase histochemistry or choline acetyltransferase immunohistochemistry, and, apparently, to contact the surface of such cells with axonal varicosities. Since these varicosities are thought to mark the sites of synaptic terminals, such juxtapositions provide strong light-microscopic evidence that intrapallidal cholinergic neurons in the rat receive a direct innervation from the striatum and are integrated into the circuitry of the basal ganglia.

Efferent connections of the ventral pallidum: evidence of a dual striato pallidofugal pathway.

Previous histological and histochemical studies have provided evidence that the globus pallidus (external pallidal segment) as conventionally delineated in the rat extends ventrally and rostrally beneath the transverse limb of the anterior commissure, invading the olfactory tubercle with its most ventral ramifications. This infracommissural subdivision of the globus pallidus or ventral pallidum (VP) is most selectively identified by being pervaded by a dense plexus of substance-P-positive striatofugal fibers; the extent of this plexus indicates that the VP behind the anterior commissure continues dorsally over some distance into the anteroventromedial part of the generally recognized (supracommissural) globus pallidus; the adjoining anterodorsolateral pallidal region, here named dorsal pallidum (DP), receives only few substance-P-positive fibers, but contains a dense plexus of enkephalin-positive striatal afferents that also pervades VP. Available autoradiographic data indicate that VP and DP receive their striatal innervation from two different subdivisions of the striatum: whereas VP is innervated by a large, anteroventromedial striatal region receiving substantial inputs from a variety of limbic and limbic-system-associated structures (and therefore called "limbic striatum"), DP receives its striatal input from an anterodorsolateral striatal sector receiving only sparse limbic afferents ("nonlimbic" striatum) but instead heavily innervated by the sensorimotor cortex. The present autoradiographic study has produced evidence that this dichotomy in the striatopallidal projection is to a large extent continued beyond the globus pallidus: whereas the efferents of DP were traced to the subthalamic nucleus and substantia nigra, those of VP were found to involve not only the subthalamic nucleus and substantia nigra but also the frontocingulate (and adjoining medial sensorimotor) cortex, the amygdala, lateral habenular and mediodorsal thalamic nucleus, hypothalamus, ventral tegmental area, and tegmental regions farther caudal and dorsal in the midbrain. These findings indicate that the ventral pallidum can convey striatopallidal outflow of limbic antecedents not only into extrapyramidal circuits but also back into the circuitry of the limbic system.

Structural asymmetries in brains of mice selected for strong lateralization.

The brains of 18 female mice from two lines selectively bred for lateralization of paw preference were investigated for morphological asymmetries in 5 horizontal sections from mid-dorsoventral planes. Cortical thickness was measured at orbitofrontal, somatosensory and lateral entorhinal regions; volume measures included the hippocampal formation and the striatum. Mice of the strongly lateralized line had stronger asymmetries in 4 of the 5 variables. Discriminant analysis showed that the two mouse lines could be differentiated best by their asymmetries in orbitofrontal cortex and hippocampus (P less than 0.02).

Afferent and efferent relationships of the basal ganglia.

A survey of the known circuitry of the basal ganglia leads to the following conclusions. (1) No complete account can yet be given of the neural pathways by which the basal ganglia affect the bulbospinal motor apparatus. Channels of exit from the basal ganglia originate from the internal pallidal segment, the pars reticulata of the substantia nigra, and the subthalamic nucleus, and each of these is directed in part rostrally to the cerebral cortex by way of the thalamus, in part caudally to the midbrain. The postsynaptic extension of the mesencephalic channels to bulbar and spinal motor neurons is largely unknown. Since the ascending channels are collectively of greatest volume, the notion remains plausible that the basal ganglia act in considerable part by modulating motor mechanisms of the cortex. (2) Recent findings in the rat suggest that the striatum is subdivided into a ventromedial, limbic system-afferented region and a dorsolateral, 'non-limbic' region largely corresponding to the main distribution of corticostriatal fibres from the motor cortex. These two subdivisions appear to give rise to different striatofugal lines, the outflow from the limbic-afferented sector partly re-entering the circuitry of the limbic system. (3) The limbic-afferented striatal sector suggests itself as an interface between the motivational and the more strictly motor aspects of movement. This suggestion is strengthened by evidence that the 'limbic striatum' seems enabled by its striatonigral efferents to modulate not only the source of its own dopamine innervation but also that of a large additional striatal region.

Ramifications of the globus pallidus in the rat as indicated by patterns of immunohistochemistry.

An attempt has been made to redefine the borders of the globus pallidus by the aid of the unique pattern of enkephalin-like and substance P-like immunoreactivity characterizing the pallidum of both monkey and rat. In preparations immunoreacted for these two peptides by the peroxidase-antiperoxidase histochemical method of Sternberger this pattern appears in the form of ribbon-like fibers (here called "woolly fibers") that have been interpreted by Haber and Elde as unstained pallidal elements (dendrites and cell bodies) each enmeshed by a plexus of thin, enkephalin- or substance P-positive striatopallidal fibers. A dense enkephalin-positive woolly-fiber plexus fills the entire external pallidal segment as conventionally defined (here called "dorsal pallidum") and extends from there in various, generally ventral, directions. The most massive, rostral extension defines the subcommissural or "ventral pallidum" of Heimer and Wilson and expands from there ventraward into the olfactory tubercle, supporting Heimer's suggestion that many of the large cells of the tubercle are pallidal neurons. Further extensions from the enkephalin-positive dorsal pallidum plexus invade the ventral striatal region (including the nucleus accumbens), a dorsal region of the amygdala, and the bed nucleus of the stria terminalis. Substance P-positive woolly fibers, like their enkephalin-positive counterparts, fill the ventral pallidum and invade the olfactory tubercle, but avoid all except a small rostroventral part of the dorsal pallidum, and do not invade the striatum, the amygdala, or the bed nucleus of the stria terminalis. On the other hand, the dense substance P-positive woolly-fiber plexus filling the internal pallidal segment (entopeduncular nucleus) expands medialward into the lateral hypothalamic region. The entopeduncular nucleus invades the hypothalamus also with a loose plexus of enkephalin-positive woolly fibers. It is suggested that woolly fibers extending outward beyond the conventionally recognized borders of the pallidum represent pallidal elements innervated by enkephalin or substance P-positive fibers arising from ventromedial striatal regions in turn innervated by limbic structures.

The amygdalostriatal projection in the rat--an anatomical study by anterograde and retrograde tracing methods.

Tritiated leucine and proline injected into the amygdaloid complex was found to label a voluminous amygdalostriatal fiber system which is distributed to all parts of the striatum except an antero-dorsolateral striatal sector. The connection is established by way of the longitudinal association bundle as well as the stria terminalis, and includes a modest (10-15%), symmetrically distributed contralateral component conveyed by the anterior commissure. Both autoradiographic findings and subsequent observations in retrograde cell-labelling (horseradish peroxidase) material indicate that the amygdalostriatal projection originates mainly from the nucleus basalis lateralis amygdalae, in much lesser volume from the nucleus basalis medialis, and minimally from the nucleus lateralis amygdalae; no other contributing amygdaloid cell group could be identified. A comparison of the present findings with earlier reports indicates that the amygdalostriatal projection widely overlaps the striatal projections from the ventral tegmental area, the mesencephalic raphe nuclei and the prefrontal cortex. Like the amygdalostriatal projection, these striatal afferents largely or entirely avoid the antero-dorsolateral striatal quadrant, which thus appears to be the striatal region most sparsely innervated by afferents originating from structures within the circuitry of the limbic system. Findings in additional autoradiographic material identify this relatively non-limbic striatal quadrant as the main region of distribution of the corticostriatal projection from the sensorimotor cortex.

Efferent connections of the substantia nigra and ventral tegmental area in the rat.

Small injections of tritiated leucine and proline confined to the ventral tegmental area (AVT) were found to label fibers ascending: (a) to the entire ventromedial half of the striatum, but most massively to the ventral striatal zone that includes the nucleus accumbens; (b) to the thalamus: lateral habenular nucleus, nuclei reuniens and centralis medius, and the most medial zone of the mediodorsal nucleus; (c) to the posterior hypothalamic nucleus and possibly the lateral hypothalamic and preoptic region; (d) to the nuclei amygdalae centralis, lateralis and medialis; (e) to the bed nucleus of the stria terminalis, the nucleus of the diagonal band, and the medial half of the lateral septal nucleus; (f) to the anteromedial (frontocingulate) cortex; and (g) to the entorhinal area. Further AVT efferents descend to the medial half of the midbrain tegmentum including an anterior region of the median raphe nucleus, to the ventral half of the central grey substance including the dorsal raphe nucleus, to the parabrachial nuclei, and to the locus coeruleus. Similar injections centered in the pars compacta of the substantia nigra (SNC) label fibers that are distributed in the striatum in an orderly medial-to-lateral arrangement, and almost entirely avoid the nucleus accumbens and olfactory tubercle. With the exception of the lateral quarter of the substantia nigra, which apparently does not project to the extreme rostral pole of the striatum, each small SNC locus, regardless of its anteroposterior localization, distributes nigrostriatal fibers throughout the length of the striatum. Descending SNC efferents are distributed to the same general regions that receive descending AVT projections, except that no SNC fibers appear to enter the locus coeruleus. Isotope injections confined to the pars reticulata (SNR) label sparse nigrostriatal fibers, and numerous nigrothalamic fibers ascending mainly to the nucleus ventromedialis and in lesser number to the parafascicular nucleus and the paralamellar zone of the nucleus mediodorsalis. Descending SNR fibers leave the nigra as a voluminous fiber bundle that bifurcates into a large nigrotectal and a smaller nigrotegmental component, the latter terminating largely in the pedunculopontine nucleus of the pontomesencephalic tegmentum.

Efferent connections of the habenular nuclei in the rat.

The efferent connections of the medial (MHb) and lateral (LHb) habenular nuclei in the rat were demonstrated autoradiographically following small injections of tritiated amino acids localized within various parts of the habenular complex. Comparison of individual cases led to the following conclusions. MHb efferents form the core portion of the fasciculus retroflexus and pass to the interpeduncular nucleus (IP) in which they terminate in a topographic pattern that refects 90 degrees rotations such that dorsal MHb projects to lateral IP, medial MHb to ventral, and lateral MHb to dorsal IP. Most MHb fibers cross in the interpeduncular necleus in the "figure 8" pattern described by Cajal, and terminate throughout the width of IP with only moderate preference for the ipsilateral side. However, the most dorsal part of MHb projects almost exclusively to the most lateral IP zone in a cluster pattern that is particularly dense on the ipsilateral side. The MHb appears to have no other significant projections, but very sparse MHb fibers may pass to the supracommissural septum and to the median raphe nucleus. Except for some fibers passing ventrally into the mediodorsal nucleus, all of the LHb efferents enter the fasciculus retroflexus and compose the mantle portion of the bundle. No LHb projections follow the stria medullaris. In the ventral tegmental area LHb efferents become organized into groups that disperse in several directions: (a) Rostrally directed fibers follow the medial forebrain bundle to the lateral, posterior and dorsomedial hypothalamic nuclei, ventromedial thalamic nucleus, lateral preoptic area, substantia innominata and ventrolateral septum. (b) Fibers turning laterally distribute to the substantia nigra, pars compacta (SNC); a small number continue through SNC to adjacent tegmentum. (c) The largest contingent of LHb efferents passes dorsocaudally into paramedian midbrain regions including median and dorsal raphe nuclei, and to adjacent tegmental reticular formation. Sparse addition LHb projections pass to the pretectal area, superior colliculus, nucleus reticularis tegmenti pontis, parabrachial nuclei and locus coeruleus. No LHb projections appear to involve the interpeduncular nucleus. All of these connections are in varying degree bilateral, with decussations in the supramammillary region, ventral tegmental area and median raphe nucleus. On the basis of differential afferent and efferent connections, the LHb can be divided into a medial (M-LHb) and a lateral (L-LHb) portion. The M-LHb, receiving most of its afferents from limbic regions and only few from globus pallidus, projects mainly to the raphe nuclei, while L-LHb, afferented mainly by globus pallidus and in lesser degree by the limbic forebrain, projects predominantly to a large region of reticular formation alongside the median raphe nucleus. Both M-LHb and L-LHb, however, project to SNC. The reported data are discussed in correlation with recent histochemical findings.

Afferent connections of the habenular nuclei in the rat. A horseradish peroxidase study, with a note on the fiber-of-passage problem.

The afferent connections of the habenular complex in the rat were examined by injecting horseradish peroxidase (HRP) into discrete portions of the habenular nuclei by microelectrophoresis. 1. HRP deposits confined to the lateral half of the lateral habenular nucleus labeled a multitude of cells in the entopeduncular nucleus. Numerous labeled cells also appeared in such cases in the lateral hypothalamus, indicating that the lateral habenular nucleus is a major convergence point of projections from these otherwise apparently quite separate cell regions. Moderate-to-small numbers of labeled cells were also found in the nuclei of the diagonal band, substantia innominata, lateral preoptic area and more caudally, in the ventral tegmental area, the region of the mesencephalic raphe, and the central gray substance. 2. HRP injected into the medial part of the lateral habenular nucleus labeled cells in the same regions, but more in the diagonal band and fewer in the entopeduncular nucleus than were labeled by more lateral injections. The contrast suggests that the projections from the basal forebrain and entopeduncular nucleus to the lateral habenular nucleus are somewhat topographically organized. 3. Injections of the medial habenular nucleus labeled an abundance of cells in the posterior parts of the supracommissural septum, but also a small number of cells in the diagonal band and mesencephalic raphe. 4. HRP injected into the stria medullaris labeled cells in all of the afore-mentioned areas and, in addition, cells in several olfactory structures, confirming that HRP may be taken up by fibers of passage and label their cells of origin, and suggesting that olfactory structures contribute fibers to the stria medullaris that do not terminate in the habenula.