The fine structure of barley aleurone cells

Summary The ultrastructural morphology of both dry and water-imbibed barley aleurone cells is described. The aleurone cell is characterized by the presence of numerous aleurone grains and spherosomes. In addition, it contains organelles typical of other plant cells including structures similar to microbodies, and rough endoplasmic reticulum characterized by the presence of numerous polyribosomes. It is inferred that the morphological specialization of aleurone cells is related to their biochemical specialization.Work supported by National Science Foundation grant GB5863. The skillful technical assistance of Mrs. Janet Price is gratefully acknowledged.     

The fine structure of rat liver cells in suspension

Summary The fine structure of liver cell suspensions prepared by two gentle methods of dispersal has been examined. Both methods result in extensive cell damage and in particular widespread rupture of the cell membrane. This damage does not occur in perfused liver slices. The observed damage to cell membranes could account for increased permeability. The limitations of such cell suspensions as models of biochemical function are discussed.     

The fine structure of differentiating interstitial cells in Hydra

Summary Interstitial cells of hydra are small undifferentiated cells containing an abundance of free ribosomes and few other cytoplasmic organelles. They are capable of differentiating into epitheliomuscular, digestive, glandular, nerve cells, and cnidoblasts. Developing epitheliomuscular and digestive cells acquire bundles of filaments, 50 Å in diameter, which later are incorporated into the muscular processes. Early gland cells develop an elaborate rough-surfaced endoplasmic reticulum and one or more Golgi apparatus. Secretory granules originate in the Golgi region eventually filling the apex of the cell. Neurons are recognized first by the presence of an elaborate Golgi apparatus, absence of a well-developed endoplasmic reticulum, and later the appearance of cytoplasmic processes. The most striking feature of nematocyst formation by cnidoblasts is the presence of a complex distribution system between protein synthesizing rough-surfaced endoplasmic reticulum and the nematocyst. This system consists of connections between cisternae of the endoplasmic reticulum with smooth Golgi vesicles which in turn are connected to minute tubules, 200 Å in diameter. The tubules extend from the Golgi region around the nematocyst finally entering the limiting membrane of the nematocyst. It is suggested that the interstitial cells of hydra represent a model system for the investigation of many aspects of cell differentiation.This work was supported by grants from the National Cancer Institute (TlCA-5055) and from the National Institute of Arthritis and Metabolic Diseases (AM-03688), National Institutes of Health, Department of Health, Education and Welfare.The author is indebted to Dr. Russell J. Barrnett for his guidance and interest throughout this investigation.     

The fine structure of mucilage secreting cells ofHibiscus esculentus pods

Summary Large secretory cells are found in the pericarp of okra capsules. In early developmental stages these cells are conspicuous because of the great quantity of Golgi apparatus-derived, PAS positive substance stored between the protoplast and the cell wall. It is suggested that these cells may play a major role in the formation of okra mucilage.     

Infrared spectroscopy of exfoliated cervical cell specimens. Proceed with caution

OBJECTIVE: To determine whether diagnostic information may be recovered from the infrared spectra of exfoliated cell specimens by using a novel spectral feature extraction method, in conjunction with linear and quadratic discriminant analysis, for spectral classification. STUDY DESIGN: Over 800 infrared spectra were included in the study, with corresponding clinical diagnoses based upon cytology and, when available, histology reports. Three sets of classification trials were carried out with the aim of distinguishing the spectra corresponding to normal specimens from CIN 1, 2 and 3. For each of these three cases, the procedure was to: (1) develop a set of provisional classification models using only a "training" subset of the spectra, and (2) test each provisional model by its ability to correctly predict the diagnoses on the basis of the remaining spectra. RESULTS: For optimal classification trials, training set classification accuracies were 68% for normal/CIN 1, 73% for normal/CIN 2 and 81% for normal/CIN 3; for the corresponding test sets the classification accuracies were 60%, 60% and 67%, respectively. CONCLUSION: The infrared spectra of exfoliated cervical cells carry information regarding the presence or absence of dysplasia, and that information is recoverable--albeit imperfectly at this stage--from the spectra of "real life" cell preparations.     

The fine structure of the kinetochore in meiotic cells of Tradescantia

Summary Observations on Tradescantia cells in the second meiotic division revealed distinct regions in meiotic chromosomes. These areas 1) consistently stain less dense than the chromosomes themselves, 2) have direct connections with the chromosomes at certain points, and 3) serve as focal points for spindle tubules during meiosis. These lighter staining regions are similar in character to kinetochores (centromeres) found in animal cells.

---

Zusammenfassung Es wurde beobachtet, daß bestimmte Regionen der Chromosomen von Tradescantia zu der zweiten meiotischen Teilung 1. durchgängig sich weniger stark färben als die Chromosomen selbst, 2. daß sie an gewissen Punkten direkte Verbindungen mit den Chromosomen haben, und 3. daß sie während der Meiosis als Sammelpunkte für Spindeltubuli dienen. Diese schwächer gefärbten Stellen werden als Kinetochoren (Centromeren) interpretiert.

---

---

This work was supported by grant GB-3330 from the National Science Foundation to Dr. Wayne Ferris, and the training grants GM 00441 and DE 00184 from the National Institutes of Health.     

Papanicolaou staining of exfoliated vaginal epithelial cells facilitates the prediction of ovulation in the giant panda

The giant panda is seasonally monoestrus, experiencing a single estrous with spontaneous ovulation in the spring. Therefore, accurate monitoring of the estrous cycle to pinpoint the time of ovulation is critical for the success of timed mating or artificial insemination. Analysis of exfoliated vaginal epithelial cells is a simple technique that rapidly yields information about the estrous status of a panda. Vaginal swabs were obtained during five estrous cycles of two nulliparous females. Cells were stained with the trichrome Papanicolaou and classified as basophils, intermediates or superficials. The color of stained cells, basophilic, acidophilic or keratinized, was recorded as a characteristic independent of the three standard cell types. The day urinary conjugates of estrogen fell from peak levels was considered the day of ovulation. A chromic shift occurred 8-9 days before ovulation when the majority of exfoliated vaginal cells changed from basophilic (blue) to acidophilic (pink) without accompanying nuclear or cytoplasmic changes. A second chromic shift was consistently observed 2 days prior to ovulation when keratinized (orange) cells replaced acidophils as the majority of vaginal cells. Monochrome staining of vaginal cells is sufficient to quantify superficial cells, which is a useful adjunct to behavioral and endocrinological data in determining estrous in the giant panda. However, the timing and duration of superficial cell elevations are substantially different between and within individual females, which limits the accuracy of timing ovulation for artificial insemination. The predictive value of vaginal cytology was greatly enhanced with the trichrome stain and evaluation of cell color.