A maternal high-fat diet modulates fetal SIRT1 histone and protein deacetylase activity in nonhuman primates.

In nonhuman primates, we previously demonstrated that a maternal high-fat diet (MHFD) induces fetal nonalcoholic fatty liver disease (NAFLD) and alters the fetal metabolome. These changes are accompanied by altered acetylation of histone H3 (H3K14ac). However, the mechanism behind this alteration in acetylation remains unknown. As SIRT1 is both a lysine deacetylase and a crucial sensor of cellular metabolism, we hypothesized that SIRT1 may be involved in fetal epigenomic alterations. Here we show that in utero exposure to a MHFD, but not maternal obesity per se, increases fetal H3K14ac with concomitant decreased SIRT1 expression and diminished in vitro protein and histone deacetylase activity. MHFD increased H3K14ac and DBC1-SIRT1 complex formation in fetal livers, both of which were abrogated with diet reversal despite persistent maternal obesity. Moreover, MHFD was associated with altered expression of known downstream effectors deregulated in NAFLD and modulated by SIRT1 (e.g., PPARΑ, PPARG, SREBF1, CYP7A1, FASN, and SCD). Finally, ex vivo purified SIRT1 retains deacetylase activity on an H3K14ac peptide substrate with preferential activity toward acetylated histone H3; mutagenesis of the catalytic domain of SIRT1 (H363Y) abrogates H3K14ac deacetylation. Our data implicate SIRT1 as a likely molecular mediator of the fetal epigenome and metabolome under MHFD conditions.

Congenital transmission of a papovavirus of the stump-tailed macaque.

Stump-tailed macaque virus, a newly recognized papovavirus of the SV40 polyoma subgroup, was demonstrated in kidney cultures from each of five stump-tailed macaque fetuses in the second half of gestation and from six adult stump-tailed macaques. Such regular presence of virus in the fetus is an unusual feature for a papovavirus.

The non-human primate oocyte and embryo as a model for women, or is it vice versa?

The role of the non-human primate (NHP) oocyte and embryo in translational research is considered here including both in vitro activities directly involving oocytes or embryos as well as animal studies that impact reproductive function. Reasons to consider NHPs as animal research models along with their limitations are summarized. A case is made that in limited instances, such as in the development and application of the assisted reproductive technologies or in the study of embryonic stem cells, the human oocyte and embryo have acted as models for the monkey. The development of strategies for the preservation of fertility is used as an example of ongoing research in the non-human primate that cannot be conducted in women for ethical reasons. In animal studies, monitoring reproductive potential, responses to embryonic stem cell transplantation, along with translational research in the field of contraceptive development for women are considered as subjects that benefit from the availability of a NHP model.

Ingestion of excessive preformed vitamin A by mothers amplifies storage of retinyl esters in early fetal livers of captive Old World monkeys.

Excessive preformed vitamin A (VA) intake is contraindicated during pregnancy because of teratogenic concerns. Recent studies have provided biochemical and histologic evidence of chronic hypervitaminosis A in captive Old World monkeys consuming laboratory diets containing high concentrations of retinyl acetate. To investigate the effects of maternal chronic overconsumption of preformed VA on VA storage in early fetal liver, we analyzed monkey fetal livers ranging from 35 to 93 d gestational age (comparable with mid-first to late second trimester in humans) for VA (n = 19) and retinoic acid (n = 9). Retinyl esters were identified in all fetal livers, and retinol, on a percentage basis, was more abundant in younger fetuses. Liver VA concentration increased with gestational age, ranging from 0.0011 to 0.26 micromol/g in the youngest (35 d) and oldest fetuses (93 d), respectively. Liver VA concentrations (mean +/- 1 standard deviation) were 0.023 +/- 0.008 micromol/g in early gestation and 0.19 +/- 0.06 micromol/g in midgestation fetuses. All-trans retinoic acid concentrations were higher in early gestation (99.2 +/- 57.0 pmol/g, n = 6) than in midgestation (18.2 +/- 6.1 pmol/g, n = 3) but were variable. Liver VA concentrations from midgestation fetuses were higher than those in fetal human and monkey livers from later stages of development, when growth and VA accumulation rates are assumed to be highest. Therefore, excessive intake of preformed VA by the mothers results in amplified early fetal liver retinyl ester storage.

Prenatal development of hypothalamic neuropeptide systems in the nonhuman primate.

In the rodent, arcuate nucleus of the hypothalamus (ARH)-derived neuropeptide Y (NPY) and proopiomelanocortin (POMC) neurons have efferent projections throughout the hypothalamus that do not fully mature until the second and third postnatal weeks. Since this process is likely completed by birth in primates we characterized the ontogeny of NPY and melanocortin systems in the fetal Japanese macaque during the late second (G100), early third (G130) and late third trimesters (G170). NPY mRNA was expressed in the ARH, paraventricular nucleus (PVH), and dorsomedial nucleus of the hypothalamus (DMH) as early as G100. ARH-derived NPY projections to the PVH were initiated at G100 but were limited and variable; however, there was a modest increase in density and number by G130. ARH-NPY/agouti-related peptide (AgRP) fiber projections to efferent target sites were completely developed by G170, but the density continued to increase in the postnatal period. In contrast to NPY/AgRP projections, alphaMSH fibers were minimal at G100 and G130 but were moderate at G170. This study also revealed several significant species differences between rodent and the nonhuman primate (NHP). There were few NPY/catecholamine projections to the PVH and ARH prior to birth, while projections were increased in the adult. A substantial proportion of the catecholamine fibers did not coexpress NPY. In addition, cocaine and amphetamine-related transcript (CART) and alpha-melanocyte stimulating hormone (alphaMSH) were not colocalized in fibers or cell bodies. As a consequence of the prenatal development of these neuropeptide systems in the NHP, the maternal environment may critically influence these circuits. Additionally, because differences exist in the neuroanatomy of NPY and melanocortin circuitry the regulation of these systems may be different in primates than in rodents.

Early development of reconstructed embryos after somatic cell nuclear transfer in a non-human primate.

To improve efficiency and assess variation in nuclear transfer techniques in non-human primates, we investigated the following factors: type of donor cell, interval between enucleation and cell injection, activation after electrical pulsing and cytokinesis inhibitors. An average of 16.4 oocytes were recovered from 91 retrievals; however, 15 (14%) additional retrieval attempts yielded no oocytes due to a failure of follicular stimulation. Oocyte maturation rates at 36, 38 and 40 h post-hCG were 46.2, 52.6 and 61.2%, respectively. The MII spindle could be seen clearly using polarized microscopy in 89.1% (614/689) of oocytes. Nuclei were seen in 42% of the NT couplets, 53% of those cleaved to the 2-cell stage and 63% of the 2-cell embryos developed to the 8-cell stage by Day 3. There was no difference in the occurrence of nuclear formation between couplets created using fibroblasts or cumulus cells, although embryos were more reliably produced with fibroblasts. The interval (2, 3 and 4 h) between enucleation and cell injection did not affect NT efficiency. Ethanol treatment after electrical pulses yielded more 2-cell NT embryos than did treatment with ionomycin, but the frequency of nuclear formation and development to the 8-cell stage was not different. Treatment of couplets with cycloheximide and cytochalasin B for 5 h after activation had no impact on NT efficiency.

Embryonic maturation of sensory terminals of primate facial hairs.

The present study examines the sequence of maturation of sensory nerve terminals that can be identified on primate facial guard hairs. At birth, the sensory innervation of both guard and vellus hairs is mature in that lanceolate, Ruffini, and free nerve ending (FNE) terminals can be identified and resemble those of the adult. Presumptive lanceolate terminals can be identified at the beginning of the third trimester of gestation, and other axons present are either Ruffini or FNEs, but definite identification is not possible. In the latter half of the second trimester only axons arranged circumferentially are present, resembling FNE or Ruffini terminals. Some of these axons directly abut the hair follicle and might eventually become lanceolate endings. The earliest nerve terminals associated with hairs cytologically resemble FNE or Ruffini terminals. At the onset of hair differentiation in the early part of the second trimester, nerves were always associated with developing epithelial hair placodes. Branching Schwann cells in the axons radiating toward the epidermis in these youngest embryos studied were best identified by electron microscopy. The early development of afferent nerve fibers in hairy skin provides an anatomical substrate for the known reflexogenic activity of primate embryos. Adequate cytologic criteria are thus available for the identification of sensory terminals in growing, differentiating, and presumably regenerating axons in primate hairy skin.

Cortisol-cortisone interrelationship in the late gestation rhesus monkey fetus in utero.

The metabolic interrelationship between cortisol (F) and cortisone (E) was studied in four long term catheterized rhesus monkey fetuses in utero during the last third of gestation. The MCR of E (50.8 +/- 5.4 liters/day) was greater than that of F (22.4 +/- 2.1, P less than 0.005) as was the plasma concentration (187.9 +/- 5.0 vs 86.1 +/- 2.5 ng/ml, P less than 0.001). The production rate of E (9.6 +/- 1.4 mg/day) was several-fold greater than for F (1.9 +/- 0.2, P less than 0.005). Of all fetal F, 79.5 +/- 7.0% was metabolized to E, and 43.4 +/- 3.9% originated from E within the fetal circulation. A significant mass of F was infused in these experiments because of the low specific activity of [14C]F. Nevertheless, the fetus was able to maintain F concentrations in the normal range. The MCR of F was similar to that which we previously found using trace amounts of [3H]F. This indicates that the fetus regulates the amount of F in the fetal compartment, probably by decreasing fetal; adrenal secretion rate. We conclude that F in the primate fetus is extensively oxidized to E. We conclude also that E is produced and metabolized much more extensively than is F. Reduction of E back to F could be an important source of fetal F, and increasing activity of this pathway, if present, could contribute to the increase in fetal F levels observed in late gestation in the primate.

5 alpha-reductase, aromatase, and androgen receptor levels in the monkey brain during fetal development.

To elucidate the metabolic fate and possible role of androgens and their derivatives during primate fetal development, aromatase (AROM), 5 alpha-reductase (5 alpha R), and androgen receptor (AR; cytosolic) levels were assessed in the brain, heart (HRT), lung (LNG), and skeletal muscle (MUS) of fetal rhesus monkeys. Analyses were performed on tissues taken on days 100 and 160 postconception. Five male and four or five female fetuses were examined at each stage. Brain tissues analyzed included medial basal hypothalamus (MBH), amygdala (AMG), cerebellum (CB), corpus callosum (CAL; splenial region), cerebral cortex (CTX), and cingulate cortex (CNG). In the following, enzyme activities are reported as picomoles per mg protein/h, while receptor levels are femtomoles per mg protein. 5 alpha R activity was measurable in all tissues. Analysis of variance revealed significant tissue differences [P less than 0.001, combined stages and sexes; CAL (2.05) greater than MBH (1.08) greater than AMG (0.63) greater than CB (0.4)-CNG-CTX-LNG-HRT-MUS (0.02); -indicates not significantly different]. A significant age x tissue interaction (P less than 0.001) was noted which could be explained by higher MBH and CAL levels in older vs. younger fetuses and higher AMG levels in younger vs. older fetuses. There was also a significant sex x tissue interaction which was attributed to higher female values in the MBH and CAL. AROM activity was detected in all tissues. Levels varied significantly among tissues [P less than 0.001, combined stages and sexes; MBH (0.80)-AMG (0.76) greater than CAL (0.4)-CNG-CB-CTX-LNG-HRT-MUS (0.07)]. Significant age (P less than 0.001) and age x tissue (P less than 0.001) effects were noted, which were due to higher MBH and AMG levels in younger vs. older fetuses. No sex difference in AROM levels was evident in any tissue. AR was measurable in all cases. Although stage and sex differences were not significant, tissue levels varied significantly [P less than 0.001; LNG (2.8)-MUS (2.6)-MBH (2.2) greater than HRT-AMG-CB-CTX-CAL-CNG (0.9)]. These findings indicate that neural and nonneural fetal primate tissues have the potential for transforming androgens to products that could have greater or lesser biological activity. AR were also noted through which dihydrotestosterone or testosterone could effect a genomic response. Since stage, tissue, and sex differences were evident in neural tissues, metabolic and receptor activities may be important for the normal differentiation of sexually dimorphic behavioral systems in monkeys as well as for potential teratogenic changes under abnormal metabolic or physiological conditions.

A second form of gonadotropin-releasing hormone (GnRH) with characteristics of chicken GnRH-II is present in the primate brain.

The primate brain was thought to contain only the GnRH known as mammalian GnRH (mGnRH). This study investigates whether a second form of GnRH exists within the primate brain. We found that brain extracts from adult stumptail and rhesus monkeys contained two forms of GnRH that were similar to mGnRH and chicken GnRH-II (cGnRH-II) based on the elution position of the peptides from HPLC and on cross-reactivity with antisera that are specific to mammalian or chicken GnRH-II in RIAs. The fetal brain of rhesus monkeys also contained mGnRH and a cGnRH-II-like peptide by the same criteria. Immunocytochemistry with a cGnRH-II-specific antiserum in adult and fetal rhesus monkeys showed immunopositive neurons generally scattered in the periaqueductal region of the midbrain, with a few positive cells in the posterior basal hypothalamus. Neurons immunopositive for cGnRH-II were fewer in number and smaller in size, with less defined nuclei and thinner neurites compared with those for mGnRH. Administration of synthetic cGnRH-II to adult rhesus monkeys resulted in a significant increase in the plasma LH concentration during the luteal phase of the menstrual cycle, but not during the midfollicular phase. We conclude that the primate brain contains mGnRH and a cGnRH-II-like molecule, although the function of the latter is unknown.

Neurogenesis of the magnocellular basal forebrain nuclei in the rhesus monkey.

The time of origin of the neurons that comprise the magnocellular basal forebrain nuclei in rhesus monkeys was determined by using [3H]thymidine autoradiography. Thirteen pregnant animals received an injection of [3H]thymidine between embryonic days 27 (E27) and E50 of their 165 day gestation, and their offspring were sacrificed during the early postnatal period. Neurons within this region were generated in a biphasic pattern. An initial burst of [3H]thymidine-labeled magnocellular neurons was first observed throughout short quiescent period, cells of the remaining anterior basal forebrain (inclusive of magnocellular neurons comprising the vertical limb of the diagonal band and the anteromedial and anterolateral regions of the nucleus basalis) were generated between E36 and E45 with a peak of neurogenesis seen on E40-E43. The intermediate division of the nucleus basalis was generated about the same time, but the peak period of neurogenesis in this region occurred slightly earlier (E36 and E40) and was completed by E43. During the second phase of neurogenesis, neurons within the posterior division of the basal forebrain were generated first, with their genesis virtually completed between E33 and E36. The genesis of all neurons comprising the magnocellular basal forebrain nuclei was completed by E48 of gestation. A general caudal to rostral gradient of neurogenesis was observed within this telencephalic region. In contrast, a neurogenic gradient was not discerned in the radial direction. The present data demonstrate that neurons comprising the basal forebrain magnocellular nuclei in monkeys are generated early in gestation with two peak times of neuronal genesis. These nuclei are among the earliest to be generated in the entire telencephalon, which, like neurons of the thalamus and cortical neurons giving rise to cortical-cortical connections, places them in a strategic position to potentially influence their target neurons within the cortical mantle that are generated later in gestation.

Cytogenesis in the monkey retina.

Time of cell origin in the retina of the rhesus monkey (Macaca mulatta) was studied by plotting the number of heavily radiolabeled nuclei in autoradiograms prepared from 2- to 6-month-old animals, each of which was exposed to a pulse of 3H-thymidine (3H-TdR) on a single embryonic (E) or postnatal (P) day. Cell birth in the monkey retina begins just after E27, and approximately 96% of cells are generated by E120. The remaining cells are produced during the last (approximately 45) prenatal days and into the first several weeks after birth. Cell genesis begins near the fovea, and proceeds towards the periphery. Cell division largely ceases in the foveal and perifoveal regions by E56. Despite extensive overlap, a class-specific sequence of cell birth was observed. Ganglion and horizontal cells, which are born first, have largely congruent periods of cell genesis with the peak between E38 and E43, and termination around E70. The first labeled cones were apparent by E33, and their highest density was achieved between E43 and E56, tapering to low values at E70, although some cones are generated in the far periphery as late as E110. Amacrine cells are next in the cell birth sequence and begin genesis at E43, reach a peak production between E56 and E85, and cease by E110. Bipolar cell birth begins at the same time as amacrines, but appears to be separate from them temporally since their production reaches a peak between E56 and E102, and persists beyond the day of birth. Müller cells and rod photoreceptors, which begin to be generated at E45, achieve a peak, and decrease in density at the same time as bipolar cells, but continue genesis at low density on the day of birth. Thus, bipolar, Müller, and rod cells have a similar time of origin. The maximal temporal separation of cell birth is between cones and amacrine cells so that cell generation exhibits two relatively distinct phases: the first phase gives rise to ganglion, horizontal, and cone cells, and the second phase to amacrine, bipolar, rod, and Müller cells. In addition, cells of the first phase are generated faster than the second phase cells, and there are differences in the topography of spread of labeled cells between the two phases. Each cell class displays a central-to-peripheral gradient in genesis, although the spatiotemporal characteristics of the gradients differ between the classes.(ABSTRACT TRUNCATED AT 400 WORDS)

Proliferation gradients in the inner ear of the monkey (Macaca mulatta) embryo.

Radioautographic studies were conducted on early developmental stages of the inner ear in monkey (Macaca mulatta) embryos ranging in age from stage 11 to stage 20 (25 to 39 days' gestation) and labeled for one hour with [3H] thymidine. The most active period of proliferation occurred at stage 13, at which time all regions of the otocyst, including the endolymphatic duct, were heavily labeled. In subsequent stages the dorsal portion of the endolymphatic duct failed to incorporate label, whereas proliferation continued in the ventral portion of the duct near its communication with the medial wall of the otocyst. The duct thus appeared to grow upward as a result of cell division from below. Mitotic activity continued in the remainder of the otocyst although there was a progressive temporal decrease in the labeling index. Spatial gradients also occurred, with dorsal and lateral regions less active than ventral and medial ones. As the otocyst differentiated, the cells in various areas became attenuated. These flattened cells were still capable of undergoing cell division, as indicated by the presence of labeled nuclei in all regions of the utricle, saccule, semicircular ducts, and cochlear duct.

The early embryogenesis of papillary (sweat duct) ridges in primate glabrous skin: the dermatotopic map of cutaneous mechanoreceptors and dermatoglyphics.

The present study documents the early innervation of the epidermis prior to the onset of differentiation of the papillary (sweat duct) ridge in glabrous digital skin of rhesus monkey embryos measuring 45, 50 and 55 mm (crown-rump) length. We observed small papillary ridges, spaced at a distance of approximately 40 microns, projecting into the dermis in the center of the distal glabrous digital pad of digits 2-5 in the 55-mm embryo. The other digital pads lacked any sign of ridge formation. A two-dimensional, approximately hexagonal grid of afferent nerves was present in the superficial dermis of all digital and palmar pads. At regular intervals of approximately 40 microns, afferent nerves ascended from the superficial dermal nerve plexus and innervated the overlying epidermis. By electron microscopy, axonal growth cones were identified contacting Merkel cells that projected several microns down into the superficial dermis in the digital pad of digit 3. Thus, the earliest wave of differentiated dorsal root ganglion neuroblasts innervates Merkel cells. Schwann cells partially encircled these growing axon tips and could be identified by the presence of rough endoplasmic reticulum and free ribosomes. The youngest embryo studied had no sign of ridge formation; however, axons ascended from the superficial dermal nerve net at 30-40-microns intervals to innervate the epidermis. We conclude that afferent nerve fibers provide a two-dimensional grid that could modulate the spacing and arrangement of the papillary or sweat duct ridges of successive digits. Such an interaction is possible between digits based on the overlapping dermatotopic maps of each rete ridge. An abnormal fingerprint could thus reflect abnormal dorsal root ganglion neuroblasts expressed through mesenchyme and epidermis.

Developmental history of the transient subplate zone in the visual and somatosensory cortex of the macaque monkey and human brain.

The cytological organization and the timetable of emergence and dissolution of the transient subplate zone subjacent to the developing visual and somatosensory cortex were studied in a series of human and monkey fetal brains. Cerebral walls processed with Nissl, Golgi, electron-microscopic, and histochemical methods show that this zone consists of migratory and postmigratory neurons, growth cones, loosely arranged axons, dendrites, synapses, and glial cells. In both species the subplate zone becomes visible at the beginning of the mid-third of gestation as a cell-poor/fiber-rich layer situated between the intermediate zone and the developing cortical plate. The subplate zone appears earlier in the somatosensory than in the visual area and reaches maximal width at the beginning of the last third of gestation in both regions. At the peak of its size the ratio between the width of the subplate zone and cortical plate in the somatosensory cortex is 2:1 in monkey and 4:1 in man while in the occipital lobe these structures have about equal width in both species. The dissolution of the subplate zone begins during the last third of gestation with degeneration of some subplate neurons and the relocation of fiber terminals into the cortex. The subplate zone disappears faster in the visual than in the somatosensory area. The present results together with our previous findings support the hypothesis that the subplate zone may serve as a "waiting" compartment for transient cellular interactions and a substrate for competition, segregation, and growth of afferents originated sequentially from the brain stem, basal forebrain, thalamus, and from the ipsi- and contralateral cerebral hemisphere. After a variable and partially overlapping time period, these fibers enter the cortical plate while the subplate zone disappears leaving only a vestige of cells scattered throughout the subcortical white matter. A comparison between species indicates that the size and duration of the subplate zone increases during mammalian evolution and culminates in human fetuses concomitantly with an enlargement of cortico-cortical fiber systems. The regional difference in the size, pattern, and resolution of the subplate zone correlates also with the pattern of cerebral convolutions. Our findings indicate that, contrary to prevailing notions, the subplate may not be a vestige of the phylogenetically old network but a transient embryonic structure that expanded during evolution to subserve the increasing number of its connections.

VEGF expression by ganglion cells in central retina before formation of the foveal depression in monkey retina: evidence of developmental hypoxia.

In macaque monkeys the foveal depression forms between fetal day (Fd) 105 and birth (Fd 172 of gestation). Before this, the incipient fovea is identified by a photoreceptor layer comprising cones almost exclusively, a multilayered ganglion cell layer (GCL), and a "domed" profile. Vessels are absent from the central retina until late in development, leading to the suggestion that the GCL in the incipient fovea may be transitorily hypoxic. Vascular endothelial growth factor (VEGF), expressed by both glial and neuronal cells and mediated by the hypoxia-inducible transcription factor (HIF)-1, is the principal factor involved in blood vessel growth in the retina. We examined VEGF expression in macaque retinas between Fd 85 and 4 months postnatal. Digoxygenin-labeled riboprobes were generated from a partial-length human cDNA polymerase chain reaction fragment, detected using fluorescence confocal microscopy, and quantified using Scion Image. High levels of VEGF mRNA were detected in astrocytes associated with developing vessels. We also detected strong expression of VEGF mRNA in the GCL at the incipient fovea prior to Fd 105, with peak labeling in the incipient fovea that declined with distance in nasal and temporal directions. By Fd 152 peak labeling was in two bands associated with development of the inner nuclear layer (INL) capillary plexus: in the inner INL where Müller and amacrine cell somas are located, and in the outer INL where horizontal cells are found. The findings suggest that at the incipient fovea the GCL is hypoxic, supporting the hypothesis that the adaptive significance of the fovea centralis is in ensuring adequate oxygen supply to neuronal elements initially located within the avascular region.

The emergence of architectonic field structure and areal borders in developing monkey sensorimotor cortex.

Adult monkey sensorimotor cortex consists of several structurally and functionally distinct areas. The developmental sequence through which the characteristic architectonic features and the borders of these areas become resolved was examined in a series of fetal, postnatal and adult monkeys by using Nissl staining, cytochrome oxidase and acetylcholinesterase histochemistry, and immunocytochemistry for GABA and the neuropeptides somatostatin, neuropeptide Y, substance P and cholecystokinin. At the youngest fetal age examined (E110), the pre- and postcentral gyri possess six clearly delineated cellular layers; populations of GABA- and neuropeptide-immunoreactive cells can be identified, but their somatic sensory cortex at E110 lacks areal cytoarchitectonic parcellation. Despite the apparent homogeneity in the cytoarchitecture of the somatic sensory cortex, incipient areal borders are revealed by staining for cytochrome oxidase and acetylcholinesterase activity, and by staining immunocytochemically for several neuropeptides. The motor cortex at E110 differs from that in adults by the presence of a prominent layer IV; a clear cytoarchitectonic border between areas 3a and 4 is detectable at E110, which is also revealed by chemoarchitectonic markers. With increasing age, the characteristic architectonic features gradually emerge and areal cytoarchitectonic borders appear, becoming adult-like by early postnatal ages. The gradual changes in cytoarchitecture are paralleled by redistributions of GABA- and neuropeptide-immunoreactive cells and fiber plexuses. The data demonstrate that the progressive refinement in cytoarchitectonic features and in the distributions of neurotransmitter- and peptide-containing cells occurs primarily during the latter third of gestation. The major changes are temporally coincident with the ingrowth of afferent axonal systems, suggesting that the establishment of connectivity may be capable of modulating finer details of structural or molecular phenotype, particularly intra-areal cytoarchitectonic features and neurotransmitter or peptide expression.

Temporal modulation of GABA(A) receptor subunit gene expression in developing monkey cerebral cortex.

In situ hybridization histochemistry was used to examine the expression of 10 GABA(A) receptor messenger RNAs corresponding to the alpha1-alpha5, beta1-beta3, gamma1 and gamma2 subunits in primary somatosensory and visual areas of macaque monkey cerebral cortex from embryonic day (E) 125 to postnatal day (P) 125. Results were compared with expression patterns in adults. In the sensorimotor cortex at E125, overall levels of all subunit transcripts were low. At E137, there was a major lamina-specific increase in all subunit messenger RNAs except gamma1. For alpha1, alpha2, alpha4, beta2, beta3 and gamma2 subunit transcripts, this increase was highest in areas 3a and 3b, particularly in layers III/IV and VI. Postnatally, there were significant decreases in all transcripts. Alpha1, alpha5, beta2 and gamma2 subunit transcripts, while still at significantly lower levels than at E137, remained expressed at levels higher than other transcripts. Unlike in rodents, there was no obvious "switch" in the major subunits expressed in fetal and adult cortex, alpha1, alpha5, beta2 and gamma2 remaining highest throughout. In area 17, the most prominently expressed subunits at earliest ages were alpha2, alpha5, beta1, beta2, beta3 and gamma2, especially in layers II/III and VI. At E150, expression for alpha2, alpha3, beta1 and beta3 subunit transcripts in these layers decreased, but levels for alpha1, alpha4, alpha5, beta2, gamma1 and gamma2 transcripts increased, particularly within layer IV. The increase at E150 was particularly marked for alpha5 transcripts, which were expressed at levels more than four times those of other transcripts. Alpha1, beta2 and gamma2 remain highest into aduthood. Fetal area 17 displayed lamina-specific patterns of expression not found in adult animals. In particular, alpha3 messenger RNAs were present in layer IVA and gamma1 transcripts were present in layer IVC at E150, despite a lack of expression in these layers in the adult. These data demonstrate increased expression of GABA(A) receptors during the period of establishment of thalamocortical and intracortical connections, and a temporal regulation that may be associated with the period of developmental plasticity.

The spatial and temporal expression of outer segment proteins during development of Macaca monkey cones.

PURPOSE: To characterize the spatial and temporal expression of key structural and phototransduction cascade proteins in the monkey cone outer segment (OS). METHODS: Retinas from Macaca monkeys from ages fetal day (Fd) 89 through adulthood were double labeled using immunofluorescence for short (S) or long/medium (L/M) wavelength-sensitive cone opsin and either a structural protein (peripherin) or a phototransduction cascade protein (alpha-transducin [alpha-T], phosphodiesterase [PDE], or rhodopsin kinase [RK]). The spatial and temporal patterns of expression for each protein at each age were determined and graphed as a percentage of retinal coverage. RESULTS: In both cone types, opsins and phototransduction proteins appear first in the fovea and last at the retinal edge. Peripherin appears concomitantly with opsin in both S and L/M cones, but S cones express peripherin and opsin 1 to 3 weeks before neighboring L/M cones. Alpha-T, PDE, and RK are expressed together in the L/M cone OS shortly after L/M opsin appears. Phototransduction proteins are not expressed in S cones until 1 to 3 weeks after the appearance of S opsin and at the same time that neighboring cones are expressing both L/M opsin and phototransduction proteins. CONCLUSIONS: The concomitant appearance of opsin and peripherin strongly suggests roles in promoting the structural integrity of the developing OS. Phototransduction cascade proteins appear in the developing OS at the same time as one another, but after opsin. The significant lag between their expression and that of S cone opsin indicates that phototransduction proteins are not essential for OS formation, nor does opsin expression trigger their expression. The different temporal but similar spatial expression patterns of phototransduction proteins within S and L/M cones suggests that some local signal(s) coordinates their appearance.

The appearance of rod opsin during monkey retinal development.

PURPOSE: To determine the temporal and spatial pattern of rod opsin appearance in Macaca monkey retina. METHODS: Frozen sections from fetal day (Fd) 55 to adulthood (birth = Fd168) containing the entire horizontal meridian were stained using Rho4D2 monoclonal antiserum visualized with immunofluorescent labeling. At Fd66, Fd79, and Fd89, retinal samples taken at known eccentricities were studied from the opposite eye using standard electron microscope methods. RESULTS: Rod opsin was detected at Fd66 in or near the fovea, and a second focus appeared at Fd75 to Fd77 near the optic disc in the nasal rod ring. The earliest opsin appeared in the apical stubs, which resembled the apical connecting cilium in the electron microscope. Staining of the entire cell body membrane, including the synaptic spherule, was present 4 to 7 days later. Opsin expression had a nasal bias with rods at the nasal ora labeled at Fd140, whereas temporal ora was not labeled until Fd155. Cell body labeling disappeared by Fd132 across central retina but persisted into the first postnatal year in far peripheral retina. Outer segment (OS) length measurements showed that rods in the rod ring had the longest OS between Fd115 and postnatal week 9. Rod OS at all retinal eccentricites continued to elongate between 11 months of age and adulthood. CONCLUSIONS: Rod opsin expression follows a foveal-to-peripheral gradient beginning at Fd66 and ending near birth. Rod opsin is detected first in the connecting cilium and slightly later in the entire cell membrane, and then cell membrane labeling disappears as the heavily labeled OS elongates. Although the first OS appear on rods near the fovea, these OS still are short at birth and do not reach adult length until after 2 years of age. The longest OS at birth are found on rods at the rod ring, suggesting that this region could have higher scotopic sensitivity than central retina at birth.