Height Changes Associated with Pigment Aggregation in <Emphasis Type="Italic">Xenopus laevis</Emphasis> Melanophores

Melanophores are pigment cells found in the skin of lower vertebrates. The brownish-black pigment melanin is stored in organelles called melanosomes. In response to different stimuli, the cells can redistribute the melanosomes, and thereby change colour. During melanosome aggregation, a height increase has been observed in fish and frog melanophores across the cell centre. The mechanism by which the cell increases its height is unknown. Changes in cell shape can alter the electrical properties of the cell, and thereby be detected in impedance measurements. We have in earlier studies of Xenopus laevis melanophores shown that pigment aggregation can be revealed as impedance changes, and therefore we were interested in investigating the height changes associated with pigment aggregation further. Accordingly, we quantified the changes in cell height by performing vertical sectioning with confocal microscopy. In analogy with theories explaining the leading edge of migrating cells, we investigated the possibility that the elevation of plasma membrane is caused by local swelling due to influx of water through HgC1₂-sensitive aquaporins. We also measured the height of the microtubule structures to assess whether they are involved in the height increase. Our results show that pigment aggregation in X. laevis melanophores resulted in a significant height increase, which was substantially larger when aggregation was induced by latrunculin than with melatonin. Moreover, the elevation of the plasma membrane did not correlate with influx of water through aquaporins or formation of new microtubules, Rather, the accumulation of granules seemed to drive the change in cell height.     

The binuclear iron site of membrane-bound methane hydroxylase from <Emphasis Type="Italic">Methylococcus capsulatus</Emphasis> (Strain M)

The particulate membrane-bound methane hydroxylase (pMMOH) was isolated from methane-oxidizing cells of Methylococcus capsulatus (strain M). At SDS PAGE, pMMOH displays three bands: at 47 (α), 27 (β), and 25 kDa (γ). The ESR spectrum of pMMOH incubated with hydrogen peroxide (final concentration 20 mM) at 4°C exhibited, along with the copper signal of type II with g = 2.05, signals of cytochrome with g = 3.0 and of high-spin ferriheme with g = 6.00 After incubation at ?30°C, additional signals with g 8.5 and 13.5 were observed. These signals, which have not been recorded previously in pMMOH preparations, are due to an intermediate of the pMMOH active site, which arises in the reaction of hydrogen peroxide with pMMOH at ?30°C. It was established that this intermediate is a high-spin dimer [Fe(III)-Fe(IV)] with S = 9/2 and different degree of rhombic distortion of structure (it is responsible for both signals). Presumably, the signal with g = 8.5 also arises from the same dimer [Fe(III)-Fe(IV)], but with S = 7/2. The presence of the intermediate [Fe(III)-Fe(IV)] in pMMOH preparations suggests that the original state of the pMMOH active site is the dimer [Fe(III)-Fe(III)] which is located in the β-subunit and cannot be detected by ESR.     

Bacterial aggregates in the tentacles of the sea anemone <Emphasis Type="Italic">Metridium senile</Emphasis>

This paper provides first information on organ-like bacterial aggregates in the tentacles of the sea anemone Metridium senile. The specimens were collected from waters near Helgoland (German Bight, North Sea) and the Orkney Islands. Tentacles were prepared for morphological inspection by light and scanning electron microscopy as well as for the phylogenetic analysis of endocytic bacteria. Bacterial aggregates are located in caverns of the tentacles’ epidermis. The aggregates are enwrapped in thin envelopes, which contain coccoid and/or rod-shaped tightly packed bacteria of different division states. Most of the bacterial cells are connected by fine filamentous structures. The phylogenetic determination is based on the sequence data of the 16S rDNA derived from tentacle material. Sequence analysis revealed three different subgroups of intratentacular proteobacteria. The dominant band, detected in all of the samples tested, showed a close relationship (98%) to a gram-negative Endozoicimonas elysicola. Two bands, only detected in tentacles of M. senile from Helgoland were assigned to Pseudomonas saccherophilia (99%), a knallgas bacterium, and to Ralstonia pickettii (100%). The bacteria represent a specific bacterial community. Their DGGE profiles do not correspond to the profiles of the planktonic bacteria generated from seawater close to the habitats of the anemones. The allocation of DNA sequences to the different morphotypes, their isolation, culturing and the elucidation of the physiological functions of intratentacular bacteria are in progress.