The Value of the Serum Neurofilament Protein Heavy Chain as a Biomarker for Peri-operative Brain Injury After Carotid Endarterectomy

This prospective study examined the value of serum neurofilament protein levels for detecting peri-operative brain damage following carotid endarterectomy. An ELISA was used for quantification of neurofilament protein heavy chain (NfH^SMI35) levels from patients undergoing endarterectomy for symptomatic (n = 17) and asymptomatic high-grade internal carotid artery stenosis (n = 30). All patients underwent diffusion-weighted brain imaging before and after the procedure. NfH^SMI35 levels were significantly higher in patients with a symptomatic carotid artery stenosis (0.131 ng/ml) if compared to asymptomatic patients (0.055 ng/ml, P = 0.01). However, serum NfH^SMI35 levels were not related to signs of brain ischemia on routine brain imaging techniques. Our pilot data suggests that raised NfH^SMI35 serum levels in patients with symptomatic carotid artery disease may be a sensitive biomarker for diffuse ischemic damage to the CNS. We conclude that NfH^SMI35 failed to qualify as a biomarker for peri-operative brain injury in CEA and factors that may have compromised the validation of this biomarker are discussed and need to be taken into account for the design of further studies.     

The ABC Transporter PXA1 and Peroxisomal β-Oxidation Are Vital for Metabolism in Mature Leaves of Arabidopsis during Extended Darkness

Fatty acid β-oxidation is essential for seedling establishment of oilseed plants, but little is known about its role in leaf metabolism of adult plants. Arabidopsis thaliana plants with loss-of-function mutations in the peroxisomal ABC-transporter1 (PXA1) or the core β-oxidation enzyme keto-acyl-thiolase 2 (KAT2) have impaired peroxisomal β-oxidation. pxa1 and kat2 plants developed severe leaf necrosis, bleached rapidly when returned to light, and died after extended dark treatment, whereas the wild type was unaffected. Dark-treated pxa1 plants showed a decrease in photosystem II efficiency early on and accumulation of free fatty acids, mostly α-linolenic acid [18:3(n-3)] and pheophorbide a, a phototoxic chlorophyll catabolite causing the rapid bleaching. Isolated wild-type and pxa1 chloroplasts challenged with comparable α-linolenic acid concentrations both showed an 80% reduction in photosynthetic electron transport, whereas intact pxa1 plants were more susceptible to the toxic effects of α-linolenic acid than the wild type. Furthermore, starch-free mutants with impaired PXA1 function showed the phenotype more quickly, indicating a link between energy metabolism and β-oxidation. We conclude that the accumulation of free polyunsaturated fatty acids causes membrane damage in pxa1 and kat2 plants and propose a model in which fatty acid respiration via peroxisomal β-oxidation plays a major role in dark-treated plants after depletion of starch reserves.     

Timing in the regulation of neural crest cell migration: retarded "maturation" of regional extracellular matrix inhibits pigment cell migration in embryos of the white axolotl mutant

In larvae of the white axolotl mutant (Ambystoma mexicanum), contrary to normal dark ones, trunk pigmentation is restricted because the epidermis is unable to support subepidermal migration of pigment cells from the neural crest (NC). This study examines whether the subepidermal extracellular matrix (ECM) is the defective component which prevents pigment cell migration in the white embryo. We transplanted subepidermal ECM, adsorbed in vivo on membrane microcarriers, from and to white and dark embryos in various combinations. White embryos have demonstrated normal NC cell migration along the medioventral pathway, and in order to test the effects of medial ECM on subepidermal migration, this ECM was similarly transplanted. Carriers with ECM attached were inserted subepidermally in host embryos at a premigratory NC stage. Control carriers without ECM and carriers with subepidermal ECM from white donors did not affect NC cell migration in white or dark embryos. In contrast, subepidermal ECM from dark donors triggered NC cell migration in the subepidermal space of both white and dark hosts. Remarkably, subepidermal ECM from white donors which were older than those normally used also stimulated migration in embryos of both strains. Likewise, medial ECM from white donors elicited migration in white as well as dark hosts. Pigment cells occurred among those NC cells that were stimulated to migrate in response to contact with ECM on carriers. These results indicate that the subepidermal ECM of the white embryo is transiently defective as a substrate for pigment cell migration, implying that "maturation" of the ECM is retarded beyond the times during which pigment cells are able to respond. In contrast, the medial ECM of the white embryo appears to mature normally. These findings suggest that the effect of the d gene is expressed regionally through the subepidermal ECM during a limited period of development. Hence, the action of the d gene seems to retard ECM maturation, bringing it out of phase with the migratory capability of the pigment cells. We propose that such a shift in relative timing of the developmental phenomena involved inhibits pigment cell migration in embryos of the white axolotl mutant and, accordingly, that the restricted pigmentation of the mutant larva is generated through heterochrony.     

The role of plankton biomass in controlling fluctuations of suspended matter in Lake Constance

The concentrations of particulate matter, expressed as dry weight (DW), particulate organic (POM), and inorganic material were measured at regular intervals in Lake Constance between February 1980 and December 1982. Maximum particle concentrations were recorded for the euphotic zone in summer (7 mg l⁻¹), while minima occurred during the early summer and in winter. Annual mean concentrations of DW within the entire water column varied between 0.6 and 0.7 mg l⁻¹. In the euphotic zone nearly 70% of DW is organic material. The inorganic particles originate either from phytoplankton (diatomaceous silicon, biogenic decalcification) or from the tributaries. Although phytoplankton biomass only comprises a relatively small proportion (i.e. 30% at maximum) of organic matter, it is the primary source of POM. Therefore, seasonal variations in phytoplankton control epilimnetic concentrations of POM in Lake Constance. Inorganic material comprises smaller proportions of suspended matter. Seasonal variations are related predominantly to fluctuations in biomass and therefore particulate inorganic matter is suggested to originate mainly from autochthonous sources. At the sampling station concentrations of inorganic particles supported by the main tributary, the Alpenrhein, only occasionally vary concomitantly with runoff.     

The Ectomesenchymal-Endodermal Interaction-System (EEIS) of Triturus alpestris in Tissue Culture

A piece of head neural fold tissue from behind the prospective ear region of a Triturus alpestris neurula was cultivated, together with a piece of ventrolateral pharynx endoderm from the same neurula, in hanging drop cultures. This system, referred to as the Ectomesenchymal-Endodermal Interaction-System (EEIS), offers insight into the visible processes of attachment, migration and differentiation of neural crest cells emigrating from the piece of neural fold.
The neural crest cells were not found to move preferably in the direction of the pharynx endoderm. Therefore, instead of chemotaxis, the concept of contact inhibition¹ provides a more satisfactory explanation for the distribution pattern of emigrating neural crest cells.
During culture, the neural crest cells differentiate into neuroblasts, pigment cells, myoblasts, chondroblasts and, after about 11 days, into perichondrial cells. After 6 days, a large number of neural crest cells, now called mesenchymal cells, persist without any visible differentiation throughout the culture.
Chondroblasts only develop from neural crest cells which have been in contact with the pharynx endoderm, as opposed to all other crest cells differentiating in the EEIS.     

D-Lactate dehydrogenase as a marker gene allows positive selection of transgenic plants

D-Lactate negatively affects Arabidopsis thaliana seedling development in a concentration-dependent manner. At media D-lactate concentrations greater than 5-10mM the development of wild-type plants is arrested shortly after germination whereas plants overexpressing the endogenous D-lactate dehydrogenase (D-LDH) detoxify D-lactate to pyruvate and survive. When the transgenic plants are further transferred to normal growth conditions they develop indistinguishably from the wild type. Thus, D-LDH was successfully established as a new marker in A. thaliana allowing selecting transgenic plants shortly after germination. The selection on D-lactate containing media adds a new optional marker system, which is especially useful if the simultaneous selection of multiple constructs is desired.     

Formation of pigment cell patterns in Triturus alpestris embryos

The distribution of melanophores and xanthopores in developing tailbud stages of Triturus alpestris was investigated. In stage 27 embryos (curved tailbuds), melanophores are distributed evenly but sparsely over the entire dorsolateral trunk. With progressive development melanophores arrange themselves into compact dorsal and lateral bands present in stage 34 embryos (9 to 10-mm-long larvae). On the inner surface of detached pieces of skin from early tailbuds which were investigated in the scanning electron microscope xanthophores were discovered in addition to and mixed with melanophores. Unlike melanophores they are invisible from outside. Later in development they occupy the zone between the melanophore bands and also the dorsal fin. Thus, formation of pigment cell patterns in Triturus embryos is a process which seems to depend on the differential sorting out of two populations of neural crest-derived chromatophore cell types.     

Developmental origins and evolution of jaws: new interpretation of "maxillary" and "mandibular"

Cartilage of the vertebrate jaw is derived from cranial neural crest cells that migrate to the first pharyngeal arch and form a dorsal "maxillary" and a ventral "mandibular" condensation. It has been assumed that the former gives rise to palatoquadrate and the latter to Meckel's (mandibular) cartilage. In anamniotes, these condensations were thought to form the framework for the bones of the adult jaw and, in amniotes, appear to prefigure the maxillary and mandibular facial prominences. Here, we directly test the contributions of these neural crest condensations in axolotl and chick embryos, as representatives of anamniote and amniote vertebrate groups, using molecular and morphological markers in combination with vital dye labeling of late-migrating cranial neural crest cells. Surprisingly, we find that both palatoquadrate and Meckel's cartilage derive solely from the ventral "mandibular" condensation. In contrast, the dorsal "maxillary" condensation contributes to trabecular cartilage of the neurocranium and forms part of the frontonasal process but does not contribute to jaw joints as previously assumed. These studies reveal the morphogenetic processes by which cranial neural crest cells within the first arch build the primordia for jaw cartilages and anterior cranium.     

Changes in the distribution of melanophores and xanthophores inTriturus alpestris embryos during their transition from the uniform to banded pattern

Summary The change in distribution of melanophores from stage 28+ (uniform melanophore pattern) to stage 34 (banded melanophore pattern) and the participation of xanthophores in these changes has been investigated inTriturus alpestris embryos by studying the social behaviour of single cells. While melanophores are clearly visible from outside the embryo at stage 28+, xanthophores cannot be recognized from the outside until after stage 34. In ultrathin sections of stage 34 embryos, xanthophores are observed alternating with melanophores in a zonal distribution (Epperlein 1982). Using detached pieces of dorsolateral trunk skin, which retain their chromatophores after detachment, the entire distribution of melanophores and xanthophores can be visualized in a scanning electron microscope (SEM). In ambiguous cases (early stages), cells were reprocessed for transmission electron microscopy (TEM) and the presence of the characteristic pigment organelles was assessed. In addition, xanthophores were specifically identified by pteridine fluorescence with dilute ammonia. Pteridines were also identified chromatographically in skin homogenates. The combination of these methods allowed precise identification and quantitative determination of melanophores and xanthophores. Both cell types were present as codistributed, biochemically differentiated cells at stage 28+. Changes in the pattern up to stage 34 were due to the rearrangement at the epidermal-mesodermal interface of a relatively fixed number of melanophores which became preferentially localised at the dorsal somite edge and at the lateral plate mesoderm, and to the distribution of an increasing number of xanthophores to subepidermal locations in the dorsal fin and between the melanophore bands. Concomitant was an increase in the thickness of the epidermal basement membrane and a change in shape of chromatophores from elongate via stellate to rosette shaped, which may be correlated with a shift from migratory to sessile phases.     

Two plastid POLLUX ion channel-like proteins are required for stress-triggered stromal Ca2+release

Two decades ago, large cation currents were discovered in the envelope membranes of Pisum sativum L. (pea) chloroplasts. The deduced K⁺-permeable channel was coined fast-activating chloroplast cation channel but its molecular identity remained elusive. To reveal candidates, we mined proteomic datasets of isolated pea envelopes. Our search uncovered distant members of the nuclear POLLUX ion channel family. Since pea is not amenable to molecular genetics, we used Arabidopsis thaliana to characterize the two gene homologs. Using several independent approaches, we show that both candidates localize to the chloroplast envelope membrane. The proteins, designated PLASTID ENVELOPE ION CHANNELS (PEC1/2), form oligomers with regulator of K⁺ conductance domains protruding into the intermembrane space. Heterologous expression of PEC1/2 rescues yeast mutants deficient in K⁺ uptake. Nuclear POLLUX ion channels cofunction with Ca²⁺ channels to generate Ca²⁺ signals, critical for establishing mycorrhizal symbiosis and root development. Chloroplasts also exhibit Ca²⁺ transients in the stroma, probably to relay abiotic and biotic cues between plastids and the nucleus via the cytosol. Our results show that pec1pec2 loss-of-function double mutants fail to trigger the characteristic stromal Ca²⁺ release observed in wild-type plants exposed to external stress stimuli. Besides this molecular abnormality, pec1pec2 double mutants do not show obvious phenotypes. Future studies of PEC proteins will help to decipher the plant’s stress-related Ca²⁺ signaling network and the role of plastids. More importantly, the discovery of PECs in the envelope membrane is another critical step towards completing the chloroplast ion transport protein inventory.