Your search keyword '"Nowakowski RS"' showing total 18 results

1. The stability of the transcriptome during the estrous cycle in four regions of the mouse brain.

Author

DiCarlo LM, Vied C, and Nowakowski RS

Subjects

Animals, Female, Gene Expression physiology, Gene Expression Profiling, Mice, Inbred C57BL, Sequence Analysis, RNA, Cerebellum metabolism, Estrous Cycle metabolism, Hippocampus metabolism, Hypothalamus metabolism, Neocortex metabolism, Transcriptome physiology

Abstract

We analyzed the transcriptome of the C57BL/6J mouse hypothalamus, hippocampus, neocortex, and cerebellum to determine estrous cycle-specific changes in these four brain regions. We found almost 16,000 genes are present in one or more of the brain areas but only 210 genes, ∼1.3%, are significantly changed as a result of the estrous cycle. The hippocampus has the largest number of differentially expressed genes (DEGs) (82), followed by the neocortex (76), hypothalamus (63), and cerebellum (26). Most of these DEGs (186/210) are differentially expressed in only one of the four brain regions. A key finding is the unique expression pattern of growth hormone (Gh) and prolactin (Prl). Gh and Prl are the only DEGs to be expressed during only one stage of the estrous cycle (metestrus). To gain insight into the function of the DEGs, we examined gene ontology and phenotype enrichment and found significant enrichment for genes associated with myelination, hormone stimulus, and abnormal hormone levels. Additionally, 61 of the 210 DEGs are known to change in response to estrogen in the brain. 50 of the 210 genes differentially expressed as a result of the estrous cycle are related to myelin and oligodendrocytes and 12 of the 63 DEGs in the hypothalamus are oligodendrocyte- and myelin-specific genes. This transcriptomic analysis reveals that gene expression in the female mouse brain is remarkably stable during the estrous cycle and demonstrates that the genes that do fluctuate are functionally related., (© 2017 Wiley Periodicals, Inc.)

Published

2017

2. Neocortical neurogenesis: morphogenetic gradients and beyond.

Author

Caviness VS Jr, Nowakowski RS, and Bhide PG

Subjects

Animals, Cell Cycle physiology, Cell Differentiation physiology, Cell Proliferation, Cyclin-Dependent Kinase Inhibitor p27 metabolism, Embryonic Stem Cells physiology, Humans, Receptor, Notch1 genetics, Receptor, Notch1 metabolism, Signal Transduction physiology, Cell Movement physiology, Neocortex cytology, Neurogenesis physiology, Neurons physiology

Abstract

Each of the five cellular layers of the cerebral neocortex is composed of a specific number of a single predominant 'class' of projection neuron. The projection neuron class is defined by its unique morphology and axonal projections to other areas of the brain. Precursor cell populations lining the embryonic lateral ventricles produce the projection neurons. The mechanisms regulating precursor cell proliferation also regulate total numbers of neurons produced at specific developmental periods and destined to a specific neocortical layer. Because the newborn neurons migrate relatively long distances to reach their final layer destinations, it is often assumed that the mechanisms governing acquisition of neuronal-class-specific characteristics, many of which become evident after neuron production, are independent of the mechanisms governing neuron production. We review evidence that suggests that the two mechanisms might be linked via operations of Notch1 and p27(Kip1), molecules known to regulate precursor cell proliferation and neuron production.

Published

2009

3. Radiation, retardation and the developing brain: time is the crucial variable.

Author

Nowakowski RS and Hayes NL

Subjects

Adolescent, Adult, Female, Gestational Age, Humans, Infant, Newborn, Pregnancy, Sweden, Time Factors, Cell Cycle radiation effects, Chernobyl Nuclear Accident, Fetal Development radiation effects, Intellectual Disability etiology, Neocortex growth & development

Abstract

Background: Widespread radiation is a threat unique to the modern world. A recent report reveals that sub-clinical damage to human foetuses between 8 and 25 weeks of gestation can result in cognitive deficits still manifest 16-18 years after birth. These previously unrecognised, long-term effects are apparently produced by a relatively short pulse of exposure to radioactive fallout at levels that were previously thought not to be deleterious. This idea is plausible given the nature of the developmental events occurring in the brain during this period of gestation., Conclusion: This exposed population should be examined for other neurological and psychiatric syndromes. If these findings are corroborated, in the event of future radiation exposures, steps should be taken to shield pregnant women who are within this window of vulnerability.

Published

2008

4. Histogenetic processes leading to the laminated neocortex: migration is only a part of the story.

Author

Caviness VS, Bhide PG, and Nowakowski RS

Subjects

Animals, Cell Lineage genetics, Gene Expression Regulation, Developmental genetics, Humans, Neocortex cytology, Neocortex physiology, Neural Pathways cytology, Neural Pathways physiology, Neurons classification, Neurons cytology, Signal Transduction genetics, Cell Differentiation physiology, Cell Movement physiology, Cell Proliferation, Neocortex embryology, Neural Pathways embryology, Neurons physiology

Abstract

The principal events of neocortical histogenesis were anticipated by work published prior to the 20th century. These were neuronal proliferation and migration and the complex events of cortical pattern formation leading to a laminated architecture where each layer is dominated by a principal neuronal class. Work that has followed has extended the knowledge of the workings of the proliferative epithelium, cellular mechanisms of migration and events through which cells are winnowed and then differentiate once their postmigratory positions are established. Work yet ahead will emphasize mechanisms that coordinate the molecular events that integrate proliferation and cell class specification in relation to the final neocortical neural system map., ((c) 2008 S. Karger AG, Basel.)

Published

2008

5. Navigating neocortical neurogenesis and neuronal specification: a positional information system encoded by neurogenetic gradients.

Author

Suter B, Nowakowski RS, Bhide PG, and Caviness VS

Subjects

Animals, Body Patterning genetics, Bromodeoxyuridine pharmacokinetics, Cell Cycle physiology, Cell Cycle Proteins, Cell Differentiation, Cerebral Ventricles cytology, Cerebral Ventricles embryology, Cyclin-Dependent Kinase Inhibitor p27 genetics, Embryo, Mammalian, Female, Homeodomain Proteins genetics, Homeodomain Proteins metabolism, In Situ Hybridization methods, In Vitro Techniques, LIM-Homeodomain Proteins, Mice, Mice, Transgenic, Models, Neurological, Neocortex embryology, Organogenesis genetics, Pregnancy, Transcription Factors genetics, Transcription Factors metabolism, Body Patterning physiology, Neocortex cytology, Neurons parasitology, Neurons physiology, Organogenesis physiology, Stem Cells physiology

Abstract

The projection neurons of the neocortex are produced in the pseudostratified ventricular epithelium (PVE) lining the embryonic lateral ventricles. Over a 7 d period in mouse, these neurons arise in an overlapping layer VI-to-II sequence and in an anterolateral to posteromedial gradient [the transverse neurogenetic gradient (TNG)]. At any time in the 7 d neurogenetic interval, a given PVE cell must know what class of precursor cell or neuron to form next. How this information is encoded in the PVE is not known. With comparative experiments in wild-type and double-transgenic mice, overexpressing the cell cycle inhibitor p27(Kip1), we show that a gradient of expression of Lhx2 (inferred from its mRNA levels), a LIM homeodomain transcription factor, together with a gradient in duration of the G1 phase of the cell cycle (T(G1)), are sufficient to specify a positional mapping system that informs the PVE cell what class of neuron to produce next. Lhx2 likely is representative of an entire class of transcription factors expressed along the TNG. This mapping system consisting of a combination of signals from two different sources is a novel perspective on the source of positional information for neuronal specification in the developing CNS.

Published

2007

6. Stable neuron numbers from cradle to grave.

Author

Nowakowski RS

Subjects

Adult, Aged, Animals, Carbon Radioisotopes, Humans, Life Expectancy, Macaca mulatta, Middle Aged, Neurons cytology, Nuclear Warfare, Neocortex cytology, Neurons physiology

Published

2006

7. Overexpression of p27 Kip 1, probability of cell cycle exit, and laminar destination of neocortical neurons.

Author

Tarui T, Takahashi T, Nowakowski RS, Hayes NL, Bhide PG, and Caviness VS

Subjects

Algorithms, Animals, Antimetabolites pharmacology, Apoptosis physiology, Bromodeoxyuridine pharmacology, Cell Count, Cell Cycle Proteins genetics, Cell Proliferation drug effects, Cyclin-Dependent Kinase Inhibitor p27, Female, Gene Expression, Idoxuridine pharmacology, Immunohistochemistry, In Situ Nick-End Labeling, Kinetics, Mice, Mice, Transgenic, Neocortex anatomy & histology, Neocortex growth & development, S Phase physiology, Tumor Suppressor Proteins genetics, Cell Cycle genetics, Cell Cycle Proteins biosynthesis, Neocortex cytology, Neurons physiology, Tumor Suppressor Proteins biosynthesis

Abstract

Neocortical projection neurons arise from a pseudostratified ventricular epithelium (PVE) from embryonic day 11 (E11) to E17 in mice. The sequence of neuron origin is systematically related to mechanisms that specify neuronal class properties including laminar fate destination. Thus, the neurons to be assembled into the deeper layers are the earliest generated, while those to be assembled into superficial layers are the later generated neurons. The sequence of neuron origin also correlates with the probability of cell cycle exit (Q) and the duration of G1-phase of the cell cycle (T(G1)) in the PVE. Both Q and T(G1) increase as neuronogenesis proceeds. We test the hypothesis that mechanisms regulating specification of neuronal laminar destination, Q and T(G1) are coordinately regulated. We find that overexpression of p27(Kip1) in the PVE from E12 to E14 increases Q but not T(G1) and that the increased Q is associated with a commensurate increase in the proportion of exiting cells that is directed to superficial layers. We conclude that mechanisms that govern specification of neocortical neuronal laminar destination are coordinately regulated with mechanisms that regulate Q and are independent of mechanisms regulatory to cell cycle duration. Moreover, they operate prior to postproliferative mechanisms necessary to neocortical laminar assembly.

Published

2005

8. Cell output, cell cycle duration and neuronal specification: a model of integrated mechanisms of the neocortical proliferative process.

Author

Caviness VS Jr, Goto T, Tarui T, Takahashi T, Bhide PG, and Nowakowski RS

Subjects

Animals, Cell Cycle physiology, Cell Division physiology, Cerebral Ventricles cytology, Cerebral Ventricles embryology, Computer Simulation, Culture Techniques, Epithelium embryology, Gene Expression Regulation, Developmental, Mice, Mice, Knockout, Microfilament Proteins deficiency, Microfilament Proteins genetics, Neocortex cytology, Neurons classification, Neurons cytology, Microfilament Proteins metabolism, Models, Neurological, Muscle Proteins, Neocortex embryology, Neocortex physiology, Neurons physiology

Abstract

The neurons of the neocortex are generated over a 6 day neuronogenetic interval that comprises 11 cell cycles. During these 11 cell cycles, the length of cell cycle increases and the proportion of cells that exits (Q) versus re-enters (P) the cell cycle changes systematically. At the same time, the fate of the neurons produced at each of the 11 cell cycles appears to be specified at least in terms of their laminar destination. As a first step towards determining the causal interrelationships of the proliferative process with the process of laminar specification, we present a two-pronged approach. This consists of (i) a mathematical model that integrates the output of the proliferative process with the laminar fate of the output and predicts the effects of induced changes in Q and P during the neuronogenetic interval on the developing and mature cortex and (ii) an experimental system that allows the manipulation of Q and P in vivo. Here we show that the predictions of the model and the results of the experiments agree. The results indicate that events affecting the output of the proliferative population affect both the number of neurons produced and their specification with regard to their laminar fate.

Published

2003

9. Size distribution of retrovirally marked lineages matches prediction from population measurements of cell cycle behavior.

Author

Cai L, Hayes NL, Takahashi T, Caviness VS Jr, and Nowakowski RS

Subjects

Animals, Cell Count, Cell Death physiology, Cell Division physiology, Cell Lineage physiology, Cell Size physiology, Female, Mice, Mice, Inbred Strains, Mice, Transgenic, Neocortex embryology, Pregnancy, Genetic Vectors, Models, Biological, Neocortex cytology, Neurons cytology, Retroviridae genetics

Abstract

Mechanisms that regulate neuron production in the developing mouse neocortex were examined by using a retroviral lineage marking method to determine the sizes of the lineages remaining in the proliferating population of the ventricular zone during the period of neuron production. The distribution of clade sizes obtained experimentally in four different injection-survival paradigms (E11-E13, E11-E14, E11-E15, and E12-E15) from a total of over 500 labeled lineages was compared with that obtained from three models in which the average behavior of the proliferating population [i.e., the proportion of cells remaining in the proliferative population (P) vs. that exiting the proliferative population (Q)] was quantitatively related to lineage size distribution. In model 1, different proportions of asymmetric, symmetric terminal, and symmetric nonterminal cell divisions coexisted during the entire developmental period. In model 2, the developmental period was divided into two epochs: During the first, asymmetric and symmetric nonterminal cell divisions occurred, but, during the second, asymmetric and symmetric terminal cell divisions occurred. In model 3, the shifts in P and Q are accounted for by changes in the proportions of the two types of symmetric cell divisions without the inclusion of any asymmetric cell divisions. The results obtained from the retroviral experiments were well accounted for by model 1 but not by model 2 or 3. These findings demonstrate that: 1) asymmetric and both types of symmetric cell divisions coexist during the entire period of neurogenesis in the mouse, 2) neuron production is regulated in the proliferative population by the independent decisions of the two daughter cells to reenter S phase, and 3) neurons are produced by both asymmetric and symmetric terminal cell divisions. In addition, the findings mean that cell death and/or tangential movements of cells in the proliferative population occur at only a low rate and that there are no proliferating lineages "reserved" to make particular laminae or cell types., (Copyright 2002 Wiley-Liss, Inc.)

Published

2002

10. Population dynamics during cell proliferation and neuronogenesis in the developing murine neocortex.

Author

Nowakowski RS, Caviness VS Jr, Takahashi T, and Hayes NL

Subjects

Animals, Cell Cycle, Cell Division, Cerebral Ventricles cytology, Cerebral Ventricles embryology, Epithelium embryology, Mathematics, Mice, Mice, Inbred Strains, Models, Neurological, Neurons cytology, Neocortex cytology, Neocortex embryology

Abstract

During the development of the neocortex, cell proliferation occurs in two specialized zones adjacent to the lateral ventricle. One of these zones, the ventricular zone, produces most of the neurons of the neocortex. The proliferating population that resides in the ventricular zone is a pseudostratified ventricular epithelium (PVE) that looks uniform in routine histological preparations, but is, in fact, an active and dynamically changing population. In the mouse, over the course of a 6-day period, the PVE produces approximately 95% of the neurons of the adult neocortex. During this time, the cell cycle of the PVE population lengthens from about 8 h to over 18 h and the progenitor population passes through a total of 11 cell cycles. This 6-day, 11-cell cycle period comprises the "neuronogenetic interval" (NI). At each passage through the cell cycle, the proportion of daughter cells that exit the cell cycle (Q cells) increases from 0 at the onset of the NI to 1 at the end of the NI. The proportion of daughter cells that re-enter the cell cycle (P cells) changes in a complementary fashion from 1 at the onset of the NI to 0 at the end of the NI. This set of systematic changes in the cell cycle and the output from the proliferative population of the PVE allows a quantitative and mathematical treatment of the expansion of the PVE and the growth of the cortical plate that nicely accounts for the observed expansion and growth of the developing neocortex. In addition, we show that the cells produced during a 2-h window of development during specific cell cycles reside in a specific set of laminae in the adult cortex, but that the distributions of the output from consecutive cell cycles overlap. These dynamic events occur in all areas of the PVE underlying the neocortex, but there is a gradient of maturation that begins in the rostrolateral neocortex near the striatotelencephalic junction and which spreads across the surface of the neocortex over a period of 24-36 h. The presence of the gradient across the hemisphere is a possible source of positional information that could be exploited during development to establish the areal borders that characterize the adult neocortex.

Published

2002

11. New neurons: extraordinary evidence or extraordinary conclusion?

Author

Nowakowski RS and Hayes NL

Subjects

Animals, Biomarkers, Brain cytology, Bromodeoxyuridine metabolism, Cell Death, Cell Division, Cell Movement, DNA Repair, DNA Replication, Immunohistochemistry, Macaca, Neocortex physiology, Neurons chemistry, Neurons physiology, Neocortex cytology, Neurons cytology

Published

2000

12. Neocortical malformation as consequence of nonadaptive regulation of neuronogenetic sequence.

Author

Caviness VS Jr, Takahashi T, and Nowakowski RS

Subjects

Algorithms, Animals, Humans, Neocortex embryology, Neocortex growth & development, Neocortex pathology, Neurons classification, Reference Values, Neocortex abnormalities, Nervous System embryology, Nervous System growth & development, Neurons physiology

Abstract

Variations in the structure of the neocortex induced by single gene mutations may be extreme or subtle. They differ from variations in neocortical structure encountered across and within species in that these "normal" structural variations are adaptive (both structurally and behaviorally), whereas those associated with disorders of development are not. Here we propose that they also differ in principle in that they represent disruptions of molecular mechanisms that are not normally regulatory to variations in the histogenetic sequence. We propose an algorithm for the operation of the neuronogenetic sequence in relation to the overall neocortical histogenetic sequence and highlight the restriction point of the G1 phase of the cell cycle as the master regulatory control point for normal coordinate structural variation across species and importantly within species. From considerations based on the anatomic evidence from neocortical malformation in humans, we illustrate in principle how this overall sequence appears to be disrupted by molecular biological linkages operating principally outside the control mechanisms responsible for the normal structural variation of the neocortex. MRDD Research Reviews 6:22-33, 2000., (Copyright 2000 Wiley-Liss, Inc.)

Published

2000

13. Independent controls for neocortical neuron production and histogenetic cell death.

Author

Verney C, Takahashi T, Bhide PG, Nowakowski RS, and Caviness VS Jr

Subjects

Animals, Animals, Newborn physiology, Cell Cycle physiology, Cell Death physiology, Cell Division physiology, In Situ Nick-End Labeling, Mice, Mice, Inbred Strains, Apoptosis physiology, Neocortex cytology, Neurons cytology, Neurons physiology

Abstract

We estimated the proportion of cells eliminated by histogenetic cell death during the first 2 postnatal weeks in areas 1, 3 and 40 of the mouse parietal neocortex. For each layer and for the subcortical white matter in each neocortical area, the number of dying cells per mm(2) was calculated and the proportionate cell death for each day of the 2-week interval was estimated. The data show that cell death proceeds essentially uniformly across the neocortical areas and layers and that it does not follow either the spatiotemporal gradient of cell cycle progression in the pseudostratified ventricular epithelium of the cerebral wall, the source of neocortical neurons, or the 'inside-out' neocortical neuronogenetic sequence. Therefore, we infer that the control mechanisms of neocortical histogenetic cell death are independent of mechanisms controlling neuronogenesis or neuronal migration but may be associated with the ingrowth, expansion and a system-wide matching of neuronal connectivity., (Copyright 2000 S. Karger AG, Basel.)

Published

2000

14. Neuronogenesis and the early events of neocortical histogenesis.

Author

Caviness VS Jr, Takahashi T, and Nowakowski RS

Subjects

Animals, Cell Differentiation physiology, Cell Division physiology, Mice, Neocortex cytology, Neocortex embryology, Neurons cytology

Published

2000

15. Sequence of neuron origin and neocortical laminar fate: relation to cell cycle of origin in the developing murine cerebral wall.

Author

Takahashi T, Goto T, Miyama S, Nowakowski RS, and Caviness VS Jr

Subjects

Aging physiology, Animals, Animals, Newborn anatomy & histology, Animals, Newborn growth & development, Brain growth & development, Cell Cycle physiology, Embryo, Mammalian cytology, Embryo, Mammalian physiology, Embryonic and Fetal Development physiology, Mice, Mice, Inbred Strains, Brain embryology, Neocortex cytology, Neurons cytology, Neurons physiology

Abstract

Neurons destined for each region of the neocortex are known to arise approximately in an "inside-to-outside" sequence from a pseudostratified ventricular epithelium (PVE). This sequence is initiated rostrolaterally and propagates caudomedially. Moreover, independently of location in the PVE, the neuronogenetic sequence in mouse is divisible into 11 cell cycles that occur over a 6 d period. Here we use a novel "birth hour" method that identifies small cohorts of neurons born during a single 2 hr period, i.e., 10-20% of a single cell cycle, which corresponds to approximately 1.5% of the 6 d neuronogenetic period. This method shows that neurons arising with the same cycle of the 11 cycle sequence in mouse have common laminar fates even if they arise from widely separated positions on the PVE (neurons of fields 1 and 40) and therefore arise at different embryonic times. Even at this high level of temporal resolution, simultaneously arising cells occupy more than one cortical layer, and there is substantial overlap in the distributions of cells arising with successive cycles. We demonstrate additionally that the laminar representation of cells arising with a given cycle is little if at all modified over the early postnatal interval of histogenetic cell death. We infer from these findings that cell cycle is a neuronogenetic counting mechanism and that this counting mechanism is integral to subsequent processes that determine cortical laminar fate.

Published

1999

16. Cyclin E-p27 opposition and regulation of the G1 phase of the cell cycle in the murine neocortical PVE: a quantitative analysis of mRNA in situ hybridization.

Author

Delalle I, Takahashi T, Nowakowski RS, Tsai LH, and Caviness VS Jr

Subjects

Animals, Cyclin B metabolism, Cyclin-Dependent Kinase 2, Cyclin-Dependent Kinases metabolism, In Situ Hybridization, Mice, Neocortex embryology, Protein Serine-Threonine Kinases metabolism, Proto-Oncogene Proteins p21(ras) metabolism, CDC2-CDC28 Kinases, Cyclin E metabolism, G1 Phase physiology, Gene Products, rex metabolism, Neocortex metabolism, RNA, Messenger metabolism

Abstract

We have analyzed the expression patterns of mRNAs of five cell cycle related proteins in the ventricular zone of the neocortical cerebral wall over the course of the neuronogenetic interval in the mouse. One set of mRNAs (cyclin E and p21) are initially expressed at high levels but expression then falls to a low asymptote. A second set (p27, cyclin B and cdk2) are initially expressed at low levels but ascend to peak levels only to decline again. These patterns divide the overall neuronogenetic interval into three phases. In phase 1 cyclin E and p21 levels of mRNA expression are high, while those of mRNAs of p27, cdk2 and cyclin B are low. In this phase the fraction of cells leaving the cycle after each mitosis, Q, is low and the duration of the G1 phase, TG1, is short. In phase 2 levels of expression of cyclin E and p21 fall to asymptote while levels of expression of mRNA of the other three proteins reach their peaks. Q increases to approach 0.5 and TG1 increases even more rapidly to approach its maximum length. In phase 3 levels of expression of cyclin E and p21 mRNAs remain low and those of the mRNAs of the other three proteins fall. TG1 becomes maximum and Q rapidly increases to 1.0. The character of these phases can be understood in part as consequences of the reciprocal regulatory influence of p27 and cyclin E and of the rate limiting functions of p27 at the restriction point and of cyclin E at the G1 to S transition.

Published

1999

17. The G1 restriction point as critical regulator of neocortical neuronogenesis.

Author

Caviness VS Jr, Takahashi T, and Nowakowski RS

Subjects

Animals, Cell Division physiology, Mice physiology, G1 Phase physiology, Neocortex cytology, Neurons cytology

Abstract

Neuronogenesis in the pseudostratified ventricular epithelium is the initial process in a succession of histogenetic events which give rise to the laminate neocortex. Here we review experimental findings in mouse which support the thesis that the restriction point of the G1 phase of the cell cycle is the critical point of regulation of the overall neuronogenetic process. The neuronogenetic interval in mouse spans 6 days. In the course of these 6 days the founder population and its progeny execute 11 cell cycles. With each successive cycle there is an increase in the fraction of postmitotic cells which leaves the cycle (the Q fraction) and also an increase in the length of the cell cycle due to an increase in the length of the G1 phase of the cycle. Q corresponds to the probability that postmitotic cells will exit the cycle at the restriction point of the G1 phase of the cell cycle. Q increases non-linearly, but the rate of change of Q with cycle (i.e., the first derivative) over the course of the neuronogenetic interval is a constant, k, which appears to be set principally by cell internal mechanisms which are species specific. Q also seems to be modulated, but at low amplitude, by a balance of mitogenic and antimitogenic influences acting from without the cell. We suggest that intracellular signal transduction systems control a general advance of Q during development and thereby determine the general developmental plan (i.e., cell number and laminar composition) of the neocortex and that external mitogens and anti-mitogens modulate this advance regionally and temporally and thereby produce regional modifications of the general plan.

Published

1999

18. A gradient in the duration of the G1 phase in the murine neocortical proliferative epithelium.

Author

Miyama S, Takahashi T, Nowakowski RS, and Caviness VS Jr

Subjects

Animals, Epithelial Cells cytology, Epithelium embryology, Gestational Age, Mice, Mice, Inbred Strains, Models, Neurological, S Phase, Cell Cycle, Embryonic and Fetal Development physiology, Neocortex cytology, Neocortex embryology

Abstract

Neuronogenesis in the neocortical pseudostratified ventricular epithelium (PVE) is initiated rostrolaterally and progresses caudo-medially as development progresses. Here we have measured the cytokinetic parameters and the fractional neuronal output parameter, Q, of laterally located early-maturing regions over the principal embryonic days (E12-E15) of neocortical neuronogenesis in the mouse. These measures are compared with ones previously made of a medial, late-maturing portion of the PVE. Laterally, as medially, the duration of the neuronogenetic interval is 6 days and comprises 11 integer cell cycles. Also, in both lateral and medial areas the length of G1 phase (TG1) increases nearly 4-fold and is the only cell cycle parameter to change. Q progresses essentially identically laterally and medially with respect to the succession of integer cell cycles. Most importantly, from E12 to E13 there is a steeply declining lateral to medial gradient in TG1. The gradient is due both to the lateral to medial graded stage of neuronogenesis and to the stepwise increase in TG1 with each integer cycle during the neuronogenetic interval. To our knowledge this gradient in TG1 of the cerebral PVE is the first cell biological gradient to be demonstrated experimentally in such an extensive proliferative epithelial sheet. We suggest that this gradient in TG1 is the cellular mechanism for positionally encoding a protomap of the neocortex within the PVE.

Published

1997