Ruth M. Hirschberg

On the structure of the adrenal gland of the common seal (Phoca vitulina vitulina).

The adrenal gland is a vitally important endocrine gland that occupies a central role in the regulatory mechanisms of the body metabolism. Environmental stress factors lead to permanent strain and overload of the body resulting in structural alterations of the adrenals that in turn are followed by hormonal imbalances. This leads to an increased susceptibility to bacterial and viral diseases. The recurrence of numerous fatalities in the different seal populations of the North Sea (during the years 1988, 1989 and 2002), of the Baikal Lake and Caspian Sea (during the years 2000 and 2001) were the motive for a morphological investigation of the species‐specific structure of the adrenal gland of the common seal in order to differentiate environmental stress‐induced pathological alterations from the physiological structure of this organ. The study was based on adrenals of 112 common seals (Phoca vitulina vitulina) using light microscopic and transmission and scanning electron microscopic methods. The phocine adrenal gland displays several structural characteristics. Originating from the connective tissue organ capsule, narrow and broad septa intersperse the adrenal cortex. These septa contain blastemata as a reserve for the regeneration of hormone‐producing cortical cells. Such blastemata are also occurring in the form of an intermediate zone in between the zona glomerulosa and zona fasciculata in the phocine adrenal cortex. Another species‐specific characteristic is an inverse part of the adrenal cortex encircling the central vein of the organ. These structural features have to be considered in assessment and definition of pathological alterations of the adrenals as observed in the form of exhausted blastema cell pools in the adrenocortex of seals perished in the mentioned phocine mass mortalities.

Microvasculature of the bovine claw demonstrated by improved micro-corrosion-casting technique.

A new and improved technique for microvascular corrosion casting was developed and verified by examination of corrosion casts of 90 bovine limbs. The described technique renders a complete filling of the vasculature of the claw even in regions that hitherto proved to be difficult regarding completeness of filling such as the dorsal area of the claw. This is demonstrated by an exemplary examination of all regions of the claw. The advantages and disadvantages of the new method are discussed. Microsc. Res. Tech. 45:184–197, 1999.

Identification of CD133-, CD34- and KDR-positive cells in the bovine ovary: A new site of vascular wall resident endothelial progenitor cells

Intense angiogenesis, vascular remodelling as well as regression of its vasculature are prerequisites for ovarian function with its cyclically developing and regressing follicles and corpora lutea. So far neither a stringent explanation for the enormous angiogenic potential of the ovary nor its cellular origins have been suggested. In an earlier study of our work group, endothelial cells were isolated from the bovine corpus luteum and cultivated in vitro. They performed vasulogenesis in vitro and showed properties of progenitor cells. The present study aimed at in situ identification of endothelial progenitor cells (EPCs) in the bovine ovary. Immunohistochemical examinations, based on the detection of KDR and CD34 co-labelled cells - a marker combination that amongst others is commonly accepted as typical for EPC identification - were performed. Hormonal cycle dependent expression varieties were analysed by the measurement of mRNA amounts of CD34 and KDR as well as the stem cell marker CD133 (Prominin-1). Ovarian samples comprising corpora lutea of varying stages (developing and mature corpus luteum, corpus luteum in regression, corpus luteum of pregnancy) from 17 adult cows were examined. Results show that specific mRNA of CD133, CD34 and KDR was expressed in ovaries of all luteal stages. Expression data analysis revealed significant differences in CD133 and CD34 expression levels between the luteal stages but no significant differences in KDR expression. CD34/KDR co-immunoreactive cells were predominantly situated within the media of arterial vessel wall. The detection of ovarian EPCs represents an important step towards further understanding of the mechanisms involved in the reproductive biology and pathophysiology of the ovary.

Alpha smooth muscle actin in the cycling ovary – an immunohistochemical study

In the ovary with its cyclically developing and regressing functional bodies and the associated intense neovascularisation and remodelling, alpha-smooth muscle actin (SMA) immunolocalisation has been frequently used as a marker to establish vessel hierarchy, in angiogenesis studies, or in studies characterising ovarian neoplasms in various species. The present study aims at detection of alpha-SMA-immunolocalisation within all structural components of the cycling bovine ovary in order to complement the hitherto available data. 27 ovaries, mainly of dairy cows ranging from 23 to 118 months of age and displaying all major stages of follicle and corpora lutea development, were collected at the abattoir and subjected to routine HE and trichrome staining as well as alpha-SMA immunohistochemistry. For this purpose, the specimens were pooled to form groups of the respective stage of corpus luteum development. The ovarian stroma displayed a notable alpha-SMA-reactivity, particularly surrounding the functional bodies. The study revealed specialised vascular modifications such as multi-directionally arranged vascular smooth muscle layers, vascular sphincters and distinct epitheloid modifications of the media in ovarian arteries. Alpha-SMA-reactivity of the microcirculation within corpora lutea of various stages allowed inferences on respective angiogenic properties. The findings were discussed focussing on functional interpretations.

Structure and age-dependent development of the turkey liver: a comparative study of a highly selected meat-type and a wild-type turkey line

In this study the macroscopic and microscopic structure of the liver of a fast growing, meat-type turkey line (British United turkeys BUT Big 6, n=25) and a wild-type turkey line (Wild Canadian turkey, n=48) were compared at the age of 4, 8, 12, 16, and 20 wk. Because the growth plates of long bones were still detectable in the 20-week-old wild-type turkeys, indicating immaturity, a group of 8 wild-type turkeys at the age of 24 wk was included in the original scope of the study. Over the term of the study, the body and liver weights of birds from the meat-type turkey line increased at a faster rate than those of the wild-type turkey line. However, the relative liver weight of the meat-type turkeys declined (from 2.7 to 0.9%) to a greater extent than that of the wild-type turkeys (from 2.8 to 1.9%), suggesting a mismatch in development between muscle weights and liver weights of the meat-type turkeys. Signs of high levels of fat storage in the liver were detected in both lines but were greater in the wild-type turkey line, suggesting a better feed conversion by the extreme-genotype birds i.e., meat-type birds. For the first time, this study presents morphologic data on the structure and arrangement of the lymphatic tissue within the healthy turkey liver, describing two different types of lymphatic aggregations within the liver parenchyma, i.e., aggregations with and without fibrous capsules. Despite differences during development, both adult meat-type and adult wild-type turkeys had similar numbers of lymphatic aggregations.

Human microvascular endothelial cells displaying reduced angiogenesis and increased uptake of lipids during in vitro culture

Human microvascular ECs from the neonatal foreskin of two donors purchased from one distributor were used in an angiogenesis assay under the same culture conditions. Different angiogenic potency was apparent in these two batches (ECang and ECnon-ang). During the cultivation period of three weeks, ECang ran through all stages of angiogenesis starting from proliferation to migration up to the formation of three-dimensional capillary-like structures. Despite of expression of endothelial markers, ECnon-ang showed excessive intracellular storage of lipids in form of multilamellar bodies and decreased angiogenic potency in contrast to its counterpart, ECang. Results indicate that lipid metabolism differs in ECang versus ECnon-ang. This study points up that these differences are based on the different donors and presents a novel and valuable model for the study of mechanisms of atherosclerosis in endothelial cells in vitro.

Gross morphology and histology of the alimentary tract of the convict cichlid Amatitlania nigrofasciata.

The primary objectives of this study were to document the macroscopic and histological structure of the alimentary tract (AT) of the convict cichlid Amatitlania nigrofasciata, because there are no data available for this omnivorous freshwater fish of the family Cichlidae. The morphology of the AT of A. nigrofasciata resembles that of related species. While having morphological criteria of the AT typical of most omnivorous fishes, such as a blind sac stomach and medium length intestine, A. nigrofasciata also has some structural peculiarities: the oesophagus is lined by a uniform stratified squamous epithelial layer with interspersed goblet cells along its entire length. Additionally, it has well-developed layers of the tunica muscularis including muscle fibre bundles that ascend into its mucosal folds. Occasionally, taste buds are present. In the transitional area between oesophagus and stomach, a prominent torus-like closure device is present. The mucosa of the stomach cannot be divided into different regions according to mucosal and morphological properties. The simple pattern of intestinal loops of A. nigrofasciata has few variations, irrespective of sex, mass and length of the individual fish. The first segment of the intestine is characterized by the largest mucososerosal ratio and the most complex mucosal surface architecture. A distinction of midgut and hindgut was not possible in A. nigrofasciata due to lack of defining structural components as described for other fish species.

Polymelous Layer Chick Displaying Additional Malformations of the Hind Gut: Case Report and In‐Depth Review of Related Literature

A case report of a male 6‐day‐old male layer chick featuring incomplete polymelia of the hind limbs and hindgut malformations is presented. The chick was submitted to computed tomography (CT) examination and subsequent anatomical dissection. Apart from the two supernumerary hind limbs, the anatomical dissection revealed additional hindgut alterations: three uniform‐sized caeca flanked the ileum, and the rectum branched into paired cloacae. The supernumerary hind limbs were localized caudal to the normal hind limbs in an inverted position and were attached to pelvic girdle elements and to a curtate pygostyle. They featured a prominent unpaired femur besides paired tibiotarsi, tarsometatarsi and species‐specific phalanges of the toes. Additionally, two separate bones attached to the caudoventral aspect of the regular hip bones were developed. The supernumerary limbs were in part mobile and received nerve and vascular supply. Digital 3D‐reconstruction based on the CT datasets revealed the osseous components of the malformed body parts. The possible morphogenesis including an in‐depth literature review and the clinical implications of the reported malformations are discussed.

Electron Microscopy in Angiogenesis Research

Electron microscopy is a powerful tool for detection and supervision of all key cell differentiation processes of in vivo neovascularisation that are also considered important in realistic in vitro models of angiogenesis, vasculogenesis and vascular remodelling. It allows detection and supervision of all major vascular differentiation processes for both, in vivo and in vitro models of neovascularisation, but preparation of samples requires experience and particular diligence in order to preserve the damageable spatial structures. The wealth of available information provided by scanning and transmission electron microscopy approaches may be useful for subsequent, e.g., biochemical or molecular, studies and thus delivers important controls for further experimental designs. In order to preserve the fragile three-dimensional cellular structures for EM, particularly of in vitro models, modified processing techniques for both TEM and SEM need to be applied that are emphasised in this chapter. E.g., different pre-embedding and sample taking techniques are provided and illustrated with hands-on photographs from the electron microscopy laboratory. Scanning electron microscopy of vascular microcorrosion casts – particularly important for studying intussusceptive processes and assessing tumour neovascularisation – is also described.